Proteolytic cleavage of the dynamin-like guanosine triphosphatase OPA1 in mitochondria is emerging as a central regulatory hub that determines mitochondrial morphology under stress and in disease. Stress-induced OPA1 processing by OMA1 triggersmitochondrial fragmentation, which is associated with mitophagy and apoptosis in vitro. Here, we identify OMA1 as a critical regulator of neuronal survival in vivo and demonstrate that stress-induced OPA1 processing by OMA1 promotes neuronal death and neuroinflammatory responses. Using mice lacking prohibitin membrane scaffolds as a model of neurodegeneration, we demonstrate that additional ablation of Oma1 delays neuronal loss and prolongs lifespan. This is accompanied by the accumulation of fusion-active, long OPA1 forms, which stabilize the mitochondrial genome but do not preserve mitochondrial cristae or respiratory chain supercomplex assembly in prohibitin-depleted neurons. Thus, long OPA1 forms can promote neuronal survival independently of cristae shape, whereas stress-induced OMA1 activation and OPA1 cleavage limit mitochondrial fusion and promote neuronal death.
Mitochondrial dynamics allow the adaptation of mitochondrial activities to varying physiological demands and ensure quality surveillance of mitochondrial function (Friedman and Nunnari, 2014; Mishra and Chan, 2014; Roy et al., 2015). Whereas mitochondrial fusion is considered to be a prosurvival mechanism (Tondera et al., 2009), fission is required for the autophagic removal of damaged mitochondria and occurs early during cell death (Youle and van der Bliek, 2012). Various cellular signals are known to determine the shape of mitochondria (Merrill and Strack, 2014; Mishra et al., 2014; Patten et al., 2014). They modulate the activity of large GTPases of the dynamin superfamily that catalyze fusion and fission of mitochondrial membranes. DRP1 mediates mitochondrial fission, whereas fusion is performed by the concerted action of mitofusins (MFN1 and MFN2) and optic atrophy 1 (OPA1) in the outer and inner mitochondrial membranes (OMM and IMM), respectively.
Acute stress and mitochondrial damage cause fragmentation of the mitochondrial network. This general stress response is often observed under pathologic conditions (Ong et al., 2013; Burté et al., 2015) and involves regulatory steps at both mitochondrial membranes. Mitochondrial depolarization triggers ubiquitin-dependent degradation of mitofusins as well as dephosphorylation and activation of DRP1 at the OMM (Cribbs and Strack, 2007; Cereghetti et al., 2008). At the same time, stress-induced proteolytic cleavage of OPA1 inhibits IMM fusion (Ishihara et al., 2006; Griparic et al., 2007; Song et al., 2007). OPA1 activity is emerging as a central regulatory hub for mitochondrial shape changes and cell survival. Loss of OPA1 impairs mitochondrial fusion, disturbs cristae morphogenesis, and increases the apoptotic sensitivity of cells (Olichon et al., 2003; Cipolat et al., 2004; Meeusen et al., 2006). On the other hand, overexpression of OPA1 protects against apoptotic and ischemic tissue damage and ameliorates phenotypes of mitochondrial disease mouse models (Cipolat et al., 2006; Civiletto et al., 2015; Varanita et al., 2015). OPA1 function is regulated by proteolytic cleavage at sites S1 and S2, which results in the balanced accumulation of noncleaved, long (L-OPA1) and cleaved, short (S-OPA1) OPA1 forms (Ishihara et al., 2006; Griparic et al., 2007). L-OPA1 is sufficient to promote mitochondrial fusion and maintain normal cristae in mouse embryonic fibroblasts (MEFs), whereas S-OPA1 appears to function in mitochondrial fission (Anand et al., 2014). Two peptidases, OMA1 and the i-AAA protease YME1L, cleave OPA1 at S1 and S2, respectively (Song et al., 2007; Ehses et al., 2009; Head et al., 2009; Stiburek et al., 2012; Anand et al., 2014). Whereas OPA1 processing by YME1L is under metabolic control (Mishra et al., 2014), OMA1 is activated upon various stress insults, resulting in the complete degradation of L-OPA1 and mitochondrial fragmentation (Ehses et al., 2009; Baker et al., 2014; Zhang et al., 2014; Quirós et al., 2015). Oma1-deficient mice exhibit impaired thermogenesis and diet-induced obesity (Quirós et al., 2012). Moreover, loss of OMA1 in cultured cells was found to protect against apoptosis (Head et al., 2009; Quirós et al., 2012; Jiang et al., 2014; Xiao et al., 2014). However, the general in vivo relevance of stress-induced OPA1 processing by OMA1, and in particular its importance for neuronal survival, is not understood.
Prohibitin membrane scaffolds are required for L-OPA1 stability and cell survival (Kasashima et al., 2008; Merkwirth et al., 2008). They form large ring complexes in the IMM, composed of multiple prohibitin 1 (PHB1) and PHB2 subunits (Tatsuta et al., 2005) constituting functional membrane domains with a defined complement of proteins and lipids (Osman et al., 2009, 2011; Richter-Dennerlein et al., 2014). Loss of PHB2 in MEFs destabilizes L-OPA1 and causes mitochondrial fragmentation, disturbances in mitochondrial ultrastructure, and increased apoptotic sensitivity (Merkwirth et al., 2008). Re-expression of noncleavable L-OPA1 restores these deficiencies, indicating that they are caused by loss of L-OPA1 (Merkwirth et al., 2008).
Forebrain neuron-specific Phb2-deficient (Phb2NKO) mice display progressive neurodegeneration, culminating in premature death (Merkwirth et al., 2012). Neuronal loss is accompanied by the destabilization of L-OPA1, defects in mitochondrial ultrastructure, loss of mitochondrial DNA (mtDNA), and late-onset mitochondrial dysfunction (Merkwirth et al., 2012). Here, we demonstrate that ablation of Oma1 prevents loss of L-OPA1, delays neurodegeneration, and extends the lifespan of Phb2NKO mice. Thus, our results establish a crucial role for OMA1 in neuronal survival in vivo.
Results and discussion
Genetic loss of Oma1 extends survival of Phb2NKO mice
We deleted Oma1 in mice lacking Phb2 specifically in forebrain neurons (Phb2NKO; Merkwirth et al., 2012) by crossing Phb2NKO mice to Oma1ko/ko mice (Quirós et al., 2012). Deletion of Phb2 resulted in premature death starting at the age of 16 wk, whereas control (Phb2fl/fl) and Oma1ko/ko mice showed normal lifespans (Fig. 1 A; Quirós et al., 2012). Notably, additional deletion of Oma1 significantly extended the median survival of Phb2NKO mice by 25% (Fig. 1 A), indicating that OMA1 limits neuronal survival in Phb2NKO mice.
We therefore analyzed brain morphology and brain weight in 18-wk-old Phb2NKO, Oma1ko/ko, and Phb2NKOOma1ko/ko mice (Fig. 1, B and C). Although Oma1ko/ko brains appeared morphologically normal, extensive forebrain atrophy was evident in Phb2NKO mice (Fig. 1 B). In contrast, brains of Phb2NKOOma1ko/ko mice were morphologically indistinguishable from those of controls (Fig. 1 B). Consistently, loss of Oma1 significantly restored brain weights of Phb2NKO mice (Fig. 1 C). Semithin sections of the hippocampal dentate gyrus (DG) from 14- and 18-wk-old animals further revealed progressive neurodegeneration in Phb2NKO mice (Fig. 1, D and E). Notably, deletion of Oma1 fully suppressed neuronal loss in the hippocampus of 14-wk-old Phb2NKO mice (Fig. 1 E); however, almost all neurons contained vacuolated structures (Fig. 1 E). Mild neuronal degeneration became apparent only in 18-wk-old Phb2NKOOma1ko/ko mice (Fig. 1, D and E). We therefore conclude that deletion of Oma1 delays the onset of neurodegeneration in Phb2NKO mice and increases their lifespan.
Oma1 deletion in Phb2NKO mice delays neuroinflammation
Neuroinflammation, characterized by the activation of microglia and astrocytes, is an early feature of neurodegenerative processes (Khandelwal et al., 2011). Neuronal loss in Phb2NKO mice is accompanied by up-regulation of glial fibrillary acidic protein (GFAP) in astrocytes, already apparent at 6 wk of age (Merkwirth et al., 2012). Immunohistochemical and immunoblot analyses of the hippocampus of 14-wk-old Phb2NKO mice revealed accumulation of GFAP and ionized calcium binding adaptor molecule 1 (IBA1), indicating astrogliosis and activated microglia, respectively (Fig. 2, A and B). In contrast, GFAP levels in hippocampal lysates, as well as GFAP and IBA1 immunoreactivities in the hippocampus of age-matched Phb2NKOOma1ko/ko mice, were similar to those of control mice (Fig. 2, A and B). GFAP protein levels and GFAP staining moderately increased in 18-wk-old Phb2NKOOma1ko/ko mice, suggesting that the neuroinflammatory response is retarded but not entirely suppressed (Fig. S1, B and C). Thus, loss of Oma1 prolongs neuronal survival and delays astrogliosis and the activation of microglia in the absence of PHB2.
To assess the expression of proinflammatory cytokines, we isolated total RNA from the hippocampus of 14-wk-old Phb2NKO, Oma1ko/ko, Phb2NKOOma1ko/ko, and control mice and analyzed mRNA levels by real-time PCR (Fig. 2 C). Whereas ablation of Oma1 did not affect cytokine expression, the relative expression of IL-1β, IL-6, and TNF was increased in Phb2NKO mice (Fig. 2 C). Remarkably, this response was completely abrogated in Phb2NKOOma1ko/ko mice (Fig. 2 C). Together, these experiments reveal that OMA1 triggers neuronal loss and early inflammatory responses in the absence of PHB2.
Oma1 deletion protects Phb2-deficient cells against apoptosis
Loss of OMA1 protects cultured cells against apoptosis (Head et al., 2009; Quirós et al., 2012; Jiang et al., 2014; Xiao et al., 2014). We have previously described that apoptosis contributes to neuronal loss in Phb2NKO mice, but have detected only a limited number of TUNEL-positive neurons (Merkwirth et al., 2012). Consistently, immunoblot analysis did not provide evidence of apoptotic or necrotic cell death or of altered autophagy in hippocampal lysates (Fig. S1 D), which is likely caused by rapid loss of Phb2-deficient neurons. We therefore used Phb2-deficient MEFs, which exhibit increased apoptotic sensitivity (Merkwirth et al., 2012), to investigate whether Oma1 deletion restores their apoptotic resistance. We depleted PHB2 from control (wild-type) and Oma1−/− MEFs and induced apoptosis by H2O2 treatment (Fig. 3, A and B). Poly(ADP ribose) polymerase and caspase-3 cleavage was undetectable in Oma1−/− cells lacking prohibitins, whereas apoptotic marker proteins accumulated in Phb2-deficient control cells (Fig. 3 A). Consistently, FACS analysis revealed that depletion of prohibitins did not affect the viability of H2O2-treated Oma1−/− cells, whereas we observed reduced viability of Phb2-deficient control MEFs upon H2O2-induced apoptosis (Fig. 3 B). Thus, Oma1 deletion in cells lacking prohibitins protects against apoptosis induced by H2O2. To further define its role in cell death pathways, we analyzed necroptotic sensitivity of MEFs lacking OMA1. Cells treated with TNF, cycloheximide, and Z-VAD-FMK undergo necroptosis, which can be inhibited by necrostatin 1 or deletion of Ripk3 (Polykratis et al., 2014). Deletion of Oma1 did not improve cell viability upon induction of necroptosis, whereas Ripk3-deficient cells were fully viable (Figs. 3 C and S1 E). In contrast, loss of Oma1 conferred resistance to apoptosis induced by TNF and cycloheximide only (Fig. 3 C). Thus, Oma1 deletion in cultured MEFs protects against apoptosis but not against necroptosis, suggesting that loss of Oma1 in Phb2NKO mice prevents apoptotic death, resulting in extended neuronal survival.
OMA1 cleaves neuronal L-OPA1 in Phb2NKO mice
We therefore turned our attention to the anti-apoptotic OMA1 substrate OPA1 (Olichon et al., 2003; Frezza et al., 2006). OPA1 splice variant 1, the predominantly expressed OPA1 isoform in the brain (Akepati et al., 2008), gives rise to L-OPA1, which is processed to S-OPA1 by OMA1. Neurons lacking prohibitins display selective loss of L-OPA1 and accumulation of S-OPA1, indicating OMA1 activation. Deletion of Oma1 in Phb2NKO mice resulted in L-OPA1 stabilization in hippocampal lysates from 14- and 18-wk-old mice (Fig. 4, A and B). Residual S-OPA1 likely resulted from YME1L-mediated OPA1 cleavage at S2. Another OMA1 substrate under stress conditions, C11orf83 (Desmurs et al., 2015), did not accumulate upon loss of OMA1 (Fig. S2 A). Hence, we conclude that neuronal ablation of Phb2 activates OMA1, triggering stress-induced processing of L-OPA1.
L-OPA1 is sufficient to mediate fusion and preserve cristae morphogenesis, rendering cultured cells resistant against apoptosis (Anand et al., 2014). We therefore assessed the ultrastructure of mitochondria in DG neurons of Phb2NKO, Oma1ko/ko, and Phb2NKOOma1ko/ko mice by transmission electron microscopy (Fig. 4 C). The ultrastructure of neuronal mitochondria was grossly unaffected in the absence of OMA1 (Fig. 4 C). In contrast, we observed aberrant neuronal mitochondria lacking cristae in Phb2NKO mice already at 6 wk of age (Fig. 4 C). Surprisingly, ablation of Oma1 in these mice did not restore cristae, but mitochondria were considerably enlarged (Fig. 4 C). Quantification of mitochondrial surface area confirmed that Phb2NKOOma1ko/ko mice contained substantially larger mitochondria, whereas mitochondrial size was altered in neither Phb2NKO nor Oma1ko/ko mice (Fig. S2, B and C). In addition, we performed immunohistochemistry on hippocampal sections from 18-wk-old mice using TOMM20-specific antibodies to visualize mitochondrial morphology (Fig. S2 D). Mitochondria appeared normal in Phb2NKO, Oma1ko/ko, and Phb2fl/fl mice but enlarged and swollen in Phb2NKOOma1ko/ko mice, reminiscent of mitochondrial morphological changes observed in Drp1-deficient hippocampal neurons (Shields et al., 2015; Oettinghaus et al., 2016).
OPA1 oligomerization contributes to the maintenance of cristae shape (Frezza et al., 2006; Patten et al., 2014). In accordance with the observed ultrastructural defects, analysis of OPA1 assembly by chemical cross-linking revealed significantly reduced OPA1 complex levels in hippocampal mitochondria isolated from 18-wk-old Phb2NKO and Phb2NKOOma1ko/ko mice (Fig. 4 D).
Thus, L-OPA1 stabilization in OMA1-deficient Phb2NKO mice does not restore OPA1 oligomerization and mitochondrial ultrastructure. The prolonged survival of PHB2-deficient neurons upon ablation of Oma1 can therefore not be explained by effects of L-OPA1 on cristae morphogenesis. Rather, our results indicate that stabilization of L-OPA1 and mitochondrial fusion ensures neuronal survival in the absence of PHB2, demonstrating a crucial role of OMA1 in neuronal survival in vivo. In light of our observations, it is conceivable that the protective effect of OPA1 overexpression in various mitochondrial disease mouse models (Civiletto et al., 2015; Varanita et al., 2015) can be attributed to L-OPA1 only, which drives fusion and can support cell survival independently of cristae morphogenesis.
Loss of Oma1 not only stabilizes L-OPA1 but also impairs the formation of S-OPA1. S-OPA1 was proposed to stimulate fission and induce mitochondrial fragmentation (Anand et al., 2014). Thus, unopposed fusion events may explain the formation of giant mitochondria that were already observed in young OMA1-deficient Phb2NKO neurons. Notably, we also observed moderately reduced accumulation of some components of the mitochondrial fission machinery in hippocampal lysates of Phb2NKOOma1ko/ko mice (Fig. S2 E).
Ablation of Oma1 in Phb2NKO mice restores mtDNA levels but does not preserve respiratory function
Oma1 deletion in Phb2NKO mice prolongs neuronal survival and extends lifespan, but Phb2NKOOma1ko/ko mice still display reduced survival. We thus reasoned that L-OPA1–independent neuronal functions of PHB2 limit the lifespan of Phb2NKOOma1ko/ko mice. We have previously described respiratory defects in Phb2NKO mice at late stages (Merkwirth et al., 2012). To examine whether OMA1 affects mitochondrial respiratory function in prohibitin-deficient neurons, we monitored the assembly of respiratory chain complexes in hippocampal mitochondria isolated from 18-wk-old Phb2NKO, Oma1ko/ko, and Phb2NKOOma1ko/ko mice by blue native (BN)-PAGE (Fig. 5, A and B). Supercomplexes composed of complexes I, III, and IV; complexes I and III; and complexes III and IV were observed in Oma1ko/ko and Phb2fl/fl control mice, which were present at markedly reduced levels in hippocampal mitochondria of Phb2NKO mice (Fig. 5 A). Additional deletion of Oma1 did not restore the formation of these supercomplexes (Fig. 5 A). Consistently, enzymatic in-gel activity assays in hippocampal mitochondria revealed decreased complex I and IV activities in both Phb2NKO and Phb2NKOOma1ko/ko mice but not in Oma1ko/ko mice (Fig. 5 B). Therefore, deletion of Oma1 does not restore respiratory function in Phb2NKO mice.
Several scenarios, which are not mutually exclusive, can be envisioned to explain respiratory deficiencies in Phb2NKOOma1ko/ko mice: loss of PHB2 may affect mtDNA stability, synthesis of mitochondrial encoded respiratory chain subunits, or assembly of the respiratory chain, irrespective of the presence of OMA1. We therefore monitored mtDNA levels in the hippocampus and striatum of 18-wk-old Phb2NKO, Oma1ko/ko, and Phb2NKOOma1ko/ko mice by quantitative real-time PCR (Figs. 5 C and S3 A). In agreement with our previous findings (Merkwirth et al., 2012), we observed a decrease of mtDNA levels to ∼40% in Phb2NKO mice (Figs. 5 C and S3 A). Conversely, mtDNA levels were slightly increased in Oma1ko/ko mice and completely restored in Phb2NKOOma1ko/ko mice (Figs. 5 C and S3 A). Thus, mtDNA levels can be maintained in neurons lacking PHB2 by stabilizing L-OPA1.
To explain respiratory deficiencies in Phb2NKOOma1ko/ko mice, we next assessed mitochondrial protein synthesis in the cerebral cortex of 14-wk-old mice (Fig. S3, B and C). As previously shown in prohibitin-depleted cells in vitro (He et al., 2012), we observed reduced mitochondrial protein synthesis in Phb2NKO mice, which was not restored by deletion of Oma1 (Fig. S3, B and C). However, impaired translation does not cause respiratory deficiencies in Phb2NKOOma1ko/ko mice, as respiratory chain complex subunits accumulated at similar steady-state levels in hippocampal mitochondria irrespective of the presence or absence of PHB2 and OMA1 (Fig. 5 D). These observations thus indicate that prohibitins affect the assembly of respiratory chain supercomplexes in a posttranslational manner, resulting in respiratory defects in PHB2-deficient neurons.
We have previously observed decreased levels and changes in the acyl chain composition of cardiolipin (CL) in mitochondrial membranes lacking PHB2, suggesting a role of PHB membrane scaffolds in CL remodeling (Richter-Dennerlein et al., 2014). CL stabilizes respiratory chain supercomplexes and maintains cristae morphogenesis (Pfeiffer et al., 2003; Schlame, 2013). An altered membrane lipid composition in the absence of PHB2 may thus affect mitochondrial cristae structure and the assembly of respiratory chain supercomplexes, irrespective of L-OPA1 stability and the presence of OMA1. Consistently, loss of DNAJC19, regulating CL metabolism and interacting with PHB complexes, disturbs the ultrastructure of mitochondria, which is not restored upon additional ablation of Oma1 (Richter-Dennerlein et al., 2014). However, to clarify the role of PHB membrane scaffolds for mitochondrial shape and function in neurons, it is necessary to define how loss of PHB2 affects the lipid composition of mitochondrial membranes specifically in affected neurons before other scenarios can be excluded. Regardless, the analysis of OMA1-deficient Phb2NKO mice unravels essential, L-OPA1–independent functions of PHB membrane scaffolds in mitochondria. These functions likely limit the lifespan of Phb2NKOOma1ko/ko mice and may explain the embryonic lethality of PHB2-deficient mice lacking OMA1 (Fig. S1 A).
Together, our results identified OMA1 as a critical regulator of neuronal survival in vivo and revealed critical roles of OMA1-mediated OPA1 processing in neurodegeneration. We demonstrate that loss of PHB membrane scaffolds activates OMA1, resulting in L-OPA1 degradation and neuronal death. Ablation of Oma1 in PHB2-deficient neurons stabilizes fusion-active L-OPA1, which supports neuronal survival by preventing apoptosis, independent of its effects on cristae morphogenesis.
Materials and methods
Neuron-specific Phb2-deficient mice (Phb2NKO) on a C57BL/6N background were generated by crossing mice in which exons 3 and 4 of the Phb2 gene were flanked by loxP sites (Phb2fl/fl) with mice expressing Cre recombinase under control of the postnatally expressed CaMKIIα promoter, allowing recombination specifically in forebrain neurons (Merkwirth et al., 2012). Oma1−/− mice on a C57BL/6N background were generated by deleting exon 2 of the Oma1 gene (Quirós et al., 2012). For the present study, Phb2NKO and Phb2NKOOma1ko/ko mice were obtained by crossing Phb2fl/fl Oma1ko/WT CaMKIIα-Cretg/WT and Phb2fl/fl Oma1ko/WT mice. Care of all animals was within institutional animal care committee guidelines, and all procedures were approved by local government authorities (Bezirksregierung Köln) and were in accordance with National Institutes of Health guidelines.
Neuropathology and ultrastructural analysis
Mice were anesthetized and perfused with 2% glutaraldehyde in PBS. Brains were removed and kept in 0.12 M phosphate buffer/2% glutaraldehyde. After treatment with osmium tetroxide, brains were embedded in Epon. Semithin (1 µm) coronal sections were cut from hippocampus, mounted with Eukitt, and observed using an Axio-Imager M2 microscope equipped with an AxioCamICc1 camera (Carl Zeiss). Images were acquired at 20× (Plan-Apochromat 20×/0.8) using AxioVision software (version 184.108.40.206; Carl Zeiss). The number of DG neurons was quantified by counting neuronal cell bodies in the whole DG area of the hippocampus. For EM analyses, ultrathin sections (70 nm) were cut and stained with uranium acetate and lead citrate (Almajan et al., 2012). Images were acquired using a transmission electron microscope at 13,500× (CM10; Philips) and an acceleration voltage of 80 kV using a camera (Gatan). Mitochondrial surface area was calculated from mitochondria imaged by transmission electron microscopy using ImageJ software (6 wk: Phb2fl/fl, n = 20; Phb2NKO, n = 31; Oma1ko/ko, n = 17; and Phb2NKOOma1ko/ko, n = 40; 14 wk: Phb2fl/fl, n = 20; Phb2NKO, n = 36; Oma1ko/ko, n = 26; and Phb2NKOOma1ko/ko, n = 43).
Animals were anesthetized and perfused intracardially with 4% paraformaldehyde. Brains were removed and conserved in 0.12 M phosphate buffer. Immunohistochemical analyses were performed on 30-µm-thick coronal free-floating sections. The following antibodies were used in this study: mouse anti-GFAP (1:350; MS-280-P0; Thermo Fisher Scientific), rabbit anti-IBA1 (1:3,000; 019-19741; Wako), and rabbit anti-TOMM20 (1:1,000; sc-11415; Santa Cruz Biotechnology, Inc.). Coronal free-floating sections were incubated for 30 min in 4% sucrose/PBS and for another 30 min in methanol. Afterward, sections were permeabilized and blocked in 10% goat serum and 0.4% Triton X-100 for 1 h. Incubation with the primary antibodies was performed overnight in 5% goat serum and 0.4% Triton X-100. After rinsing with PBS, secondary antibodies (Alexa Fluor anti–mouse 488, anti–rabbit 488, and anti–rabbit 568; Invitrogen) diluted in 5% goat serum were applied for 2 h, and sections were mounted with Fluorsave. Images were acquired using an Axio-Imager M2 microscope equipped with an AxioCamICc1 camera (Carl Zeiss), 5× (EC Plan-Neofluar 5×/0.16 Ph 1), or 10× (EC Plan-Neofluar 10×/0.3 Ph 1) objective lenses and AxioVision software for GFAP and IBA1 stains as well as an UltraVIEW VoX spinning disc confocal microscope (PerkinElmer) on a TiE microscope (Nikon) equipped with a 60× objective lens (Plan-Apo Tirf 60×/1.49 oil), a camera (AMCCD C9100-50; CamLink), and Volocity software (PerkinElmer) for TOMM20 immunohistochemistry. Analyses were performed on at least three mice per genotype.
Determination of cytokine mRNA levels by RT-PCR
Total RNA was isolated from brain tissues using the NucleoSpin RNA kit (Macherey-Nagel). cDNA was synthesized with the SuperScript III First-Strand Synthesis System kit (Invitrogen). Quantitative real-time PCR analysis was performed with the ABI PRISM 7000 sequence detection system using Power SYBR Green PCR Master Mix (Applied Biosystems). Transcript levels were normalized to Gapdh expression.
Isolation of mitochondria
Mitochondria-enriched membrane fractions were isolated by differential centrifugation. Brain tissues were dissected from mice, cut into small pieces, and homogenized in an appropriate amount of isolation buffer (20 mM Hepes, pH 7.4, 220 mM d-mannitol, 70 mM sucrose, 2 mM EGTA, and 0.1% BSA [wt/vol]) at 1,000 rpm in a motor-driven dounce homogenizer (Braun). The crude homogenate was centrifuged at 1,000 g for 10 min to pellet nuclei and unbroken cells, and the pellet obtained was homogenized again. Subsequently, mitochondria were collected by centrifugation of the supernatants (8,000 g for 10 min) and resuspended in freezing buffer (10 mM Hepes-KOH, pH 7.4, and 500 mM sucrose). Protein concentration was determined using Bradford protein assays, and mitochondria were kept frozen until further use.
Brain tissues were dissected and homogenized using a Polytron homogenizer (IKA Werke) in ice-cold lysis buffer (50 mM Hepes/KOH, pH 7.4, 10 mM EDTA, 50 mM NaCl, 100 mM NaF, 1% Triton X-100, and 0.1% SDS supplemented with 20 µg/ml aprotinin, 2 mM benzamidine, 10 mM sodium orthovanadate, and complete protease inhibitor cocktail mix; Roche). Cells were harvested by scraping and lysed in lysis buffer (50 mM Tris-HCl, pH 7.4, 1 mM EDTA, 150 mM NaCl, 1% Triton X-100, 0.1% SDS, 0.5% sodium deoxycholate, and complete protease inhibitor cocktail mix). 50–100 µg total protein was separated by SDS-PAGE, transferred to nitrocellulose membranes, and subjected to immunoblotting using the following antibodies: mouse anti-OPA1 (612606; BD Biosciences), mouse anti-VDAC/Porin (529536; Calbiochem), rabbit anti-GFAP (Z0334; Dako), mouse anti-GAPDH (sc-32233; Santa Cruz Biotechnology, Inc.), mouse anti-SDHA (459200; Invitrogen), rabbit anti-HSPA9 (14887-1-AP; ProteinTech), rabbit anti–poly(ADP ribose) polymerase (9542; Cell Signaling), rabbit anti–cleaved caspase-3 (9661; Cell Signaling), rabbit anti-PHB2 (611802; BioLegend), rabbit anti-PHB1 (603102; BioLegend), mouse anti–β-actin (A5441; Sigma-Aldrich), mouse anti-Spectrin (MAB1622; Merck Millipore), mouse anti-p62 (H00008878-M01; Abnova), rabbit anti-LC3 (PM036; MBL), rabbit anti-RIPK3 (ADI-905-242; Enzo), rabbit anti-MFN2 (ab50838; Abcam), mouse anti-DRP1 (611112; BD Biosciences), rabbit anti–P-DRP1 (S616; 3455; Cell Signaling), rabbit anti-MID49 (16413-1-AP; ProteinTech), rabbit anti-MID51 (20164-1-AP; ProteinTech), rabbit anti-FIS1 (10956-1-AP; ProteinTech), rabbit anti-MFF (17090-1-AP; ProteinTech), mouse anti-NDUFA9 (459100; Invitrogen), mouse anti-UQCRC2 (459220; Invitrogen), mouse anti-MTCO1 (459600; Invitrogen), mouse anti-ATP5A (459240; Invitrogen), mouse anti-NDUFB6 (A21359; Invitrogen), mouse anti-COX5b (459110; Invitrogen), and mouse anti-C11orf83 (Ab-1342-YOM; Primm).
MEFs were cultured at 37°C (humidified, 5% CO2 [vol/vol]) in DMEM-GlutaMAX (Thermo Fisher Scientific) supplemented with 10% (vol/vol) FBS, 1 mM sodium pyruvate, and nonessential amino acids. siRNA transfections using Lipofectamine RNAiMAX (Thermo Fisher Scientific) were performed according to the manufacturer’s protocol. Cells were grown for 72 h and used for further experiments. The efficiency of down-regulation was assessed by immunoblotting.
Cell death analysis
MEFs were treated with 1 mM H2O2 for 7 h to induce apoptosis. Apoptotic cell death was assessed by Annexin V and 7-AAD staining, and cells were analyzed by flow cytometry (FACS Aria III; BD Biosciences). The accumulation of apoptotic marker proteins was analyzed by immunoblotting. To induce necroptosis, MEFs were pretreated with 40 µM necrostatin 1 and/or 50 µM Z-VAD-FMK for 2 h and then treated with 20 ng/ml hTNFα, 10 µg/ml cycloheximide, 40 µM necrostatin-1, and/or 50 µM Z-VAD-FMK for 8 h. Afterward, cell viability was measured using CellTiter-Glo luminescent cell viability assay (Promega) according to the manufacturer’s instructions.
Analysis of OPA1 oligomerization
OPA1 oligomerization was analyzed by cross-linking (Patten et al., 2014) and BN-PAGE. For cross-linking, isolated hippocampal mitochondria were suspended in freezing buffer (0.5 M sucrose and 10 mM Hepes, pH 7.4) at 0.5 µg mitochondrial protein/µl. 1 mM EDC (Thermo Fisher Scientific) was added for 30 min at RT, and the reaction was quenched with 0.1% β-mercaptoethanol for 15 min. Samples were analyzed by immunoblotting.
Hippocampal mitochondria (100 µg) were solubilized in 50 mM NaCl, 5 mM 6-aminohexanoic acid, 50 mM imidazole/HCl, pH 7, 10% (vol/vol) glycerol, and 50 mM KPi-buffer, pH 7.4, supplemented with detergent (8 g digitonin/g protein). After extraction for 30 min and a clarifying spin at 16,100 g for 30 min, samples were separated by 3%–13% BN-PAGE. For in-gel activity staining, native gels were incubated with substrates specific for complex I (2 mM Tris/HCl, pH 7.4, 0.1 mg/ml NADH, and 2.5 mg/ml Nitrotetrazolium blue) or complex IV (0.5 mg/ml DAB, 50 mM phosphate buffer, pH 7.4, 20 µg/ml catalase, 1 mg/ml reduced cytochrome c, and 75 mg/ml sucrose) as described previously (Zerbetto et al., 1997).
Quantification of mtDNA
Total DNA was isolated from hippocampus and striatum. Real-time amplification was performed using SYBR Green PCR Master Mix (Applied Biosystem). mtDNA was detected with primers specific for the murine COI gene. Amplification of the nuclear-encoded murine RNaseP gene was used as a reference. Relative abundance of mtDNA was determined using a comparative method (2−ΔΔCt).
In organello translation
Mitochondria were isolated from freshly dissected cerebral cortex. 500 µg mitochondria was resuspended in 500 µl translation buffer (100 mM mannitol, 10 mM sodium succinate, 80 mM KCl, 5 mM MgCl2, 25 mM Hepes-KOH, pH 7.4, 1 mM KPi, pH 7.4, 5 mM ATP, 20 µM GTP, and 6 mM creatine phosphate) containing all amino acids (60 µg/ml) except methionine. Afterward, protein synthesis was performed for 1 h at 37°C in the presence of [35S]Met (0.05 mCi/ml). Mitochondria were pelleted, resuspended in Laemmli buffer, and separated by SDS-PAGE. Newly synthesized mitochondrial proteins were visualized by autoradiography. The total radioactive signal was quantified using ImageJ.
For statistical analyses, at least three independent experiments were performed. Data are represented as mean ± SD. Statistical significance was determined by t test.
Online supplemental material
Fig. S1 shows the functional relationship of OMA1 with inflammatory and cell death pathways. Fig. S2 shows altered mitochondrial morphology in Phb2NKOOma1ko/ko mice. Fig. S3 shows stabilization of mtDNA in the striatum of Phb2NKOOma1ko/ko mice and impaired mitochondrial translation in Phb2NKO and Phb2NKOOma1ko/ko mice. Online supplemental material is available at http://www.jcb.org/cgi/content/full/jcb.201507022/DC1.
We thank Esther Barth and Helga Bank for excellent technical support, Shuaiyu Wang for help in immunohistochemistry, Dr. Gunter Rappl (Central Cell Sort Facility, Cologne, Germany) for help in flow cytometry, and Dr. Astrid Schauss (Cologne Excellence Cluster on Cellular Stress Responses in Aging-Associated Diseases imaging facility) for support in image acquisition.
This work was supported by an European Molecular Biology Organization long-term fellowship to R. Richter-Dennerlein and grants of the Deutsche Forschungsgemeinschaft and the European Research Council to T. Langer and by the Ministerio de Economía y Competitividad (Spain) to C. López-Otín. The Instituto Universitario de Oncología is supported by Fundación Bancaria Caja de Ahorros de Asturias. C. López-Otín is an Investigator of the Botín Foundation supported by Banco Santander through its Santander Universities Global Division.
The authors declare no competing financial interests.
- Abbreviations used in this paper:
- blue native
- dentate gyrus
- glial fibrillary acidic protein
- ionized calcium binding adaptor molecule 1
- inner mitochondrial membrane
- mouse embryonic fibroblast
- mitochondrial DNA
- outer mitochondrial membrane
- Submitted: 6 July 2015
- Accepted: 14 December 2015
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