FLY 2016, VOL. 10, NO. 1, 19–24 http://dx.doi.org/10.1080/19336934.2016.1174353
EXTRA VIEW
Mitochondrial retrograde signaling in the Drosophila nervous system and beyond Olivia F. Duncan and Joseph M. Bateman Wolfson Center for Age-Related Diseases, King’s College London, Guy’s Campus, London, UK
ABSTRACT
ARTICLE HISTORY
Mitochondrial dysfunction has been suggested to contribute to neurodegenerative diseases, including Alzheimer and Parkinson disease. Cells respond to changes in the functional state of mitochondria via retrograde signaling pathways from the mitochondria to the nucleus, but little is known about retrograde signaling in the nervous system. We have recently shown that inhibition of retrograde signaling reduces the impact of neuronal mitochondrial dysfunction. We performed a study designed to characterize the mitochondrial retrograde signaling pathway in the Drosophila nervous system. Using several different models we found that neuronal specific mitochondrial dysfunction results in defects in synapse development and neuronal function. Moreover, we identified the Drosophila hypoxia inducible factor a (HIFa) ortholog Sima as a key neuronal transcriptional regulator. Knockdown of sima restores function in several Drosophila models of mitochondrial dysfunction, including models of human disease. Here we discuss these findings and speculate on the potential benefits of inhibition of retrograde signaling. We also describe how our results relate to other studies of mitochondrial retrograde signaling and the potential therapeutic applications of these discoveries.
Received 20 January 2016 Revised 24 March 2016 Accepted 30 March 2016
Mitochondria produce the majority of cellular energy in the form of ATP and play key roles in amino acid synthesis, calcium buffering, iron-sulfur cluster synthesis, generation of reactive oxygen species (ROS) and apoptosis. Dysfunction of this multifunctional organelle is associated with a wide range of disorders, from diabetes to cancer and neurodegeneration.1,2 The high metabolic demand of the nervous system makes it particularly sensitive to mitochondrial deficits. Altered mitochondrial morphology, decreased complex I activity and reduced mitochondrial DNA (mtDNA) levels are observed in the cortex of Alzheimer disease (AD) patients.3-5 Complex I deficiencies and increased production of ROS are also detected in the substantia nigra pars compacta in Parkinson disease patients.6,7 Similarly, complex I deficiency and mtDNA loss are observed in the prefrontal cortex of patients with Parkinson disease dementia.8,9 The mitochondrial retrograde response is a signaling pathway that enables cells to respond to changes in the functional state of mitochondria. Mitochondrial retrograde signaling is a pathway of communication from mitochondria to the nucleus, resulting in changes in
KEYWORDS
Drosophila; HIFa; Mitochondria; neuron; neurodegeneration; retrograde signaling
nuclear gene expression (Fig. 1).10 This is opposite to anterograde signaling from the nucleus to mitochondria. Retrograde signaling varies according to the context, ranging from cellular metabolic changes to cell cycle arrest and even modification of the systemic integrated stress response.10-12 Retrograde signaling has been well characterized in budding yeast and has been linked to the mechanistic target of rapamycin (mTOR) pathway in this model.13 In yeast, reduced glutamine levels activate the retrograde response,14 resulting in nuclear translocation of the Rtg1/Rtg3 transcriptional heterodimer.15 Activation of retrograde signaling can result from changes in cellular metabolic status, AMP: ATP ratio, ROS levels, Ca2C concentration, or compromised mitochondrial membrane potential.10,16-18 A number of different mitochondrial retrograde signaling pathways have been identified in mammalian cells. For example, increased cytosolic Ca2C concentration activates cAMP-responsive element-binding protein (CREB), triggering a transcriptional response.19 Other pathways such as mTOR, NFkB and Sirt1 are also implicated in the mammalian retrograde response.20 These studies have focused on proliferating cells and it
CONTACT Joseph M. Bateman [email protected] Wolfson Center for Age-Related Diseases, King’s College London, Guy’s Campus, London SE1 1UL, UK. Color versions of one or more of the figures in the article can be found online at www.tandfonline.com/kfly © 2016 Taylor & Francis
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Figure 1. A model for neuronal mitochondrial retrograde signaling in Drosophila. Mitochondrial dysfunction causes reduced mitochondrial membrane potential (DC) and triggers the retrograde response. In the Drosophila nervous system HIFa (Sima) regulates retrograde response genes to reprogram neurons by changing the metabolic state of the cell and inhibiting protein translation.
is unclear how relevant these pathways are to mitochondrial retrograde signaling in post-mitotic neurons. To address this we recently developed a model to investigate the mitochondrial retrograde response in the Drosophila central nervous system (CNS). We characterized the transcriptional response to mitochondrial dysfunction caused either by overexpression of mitochondrial transcription factor A (TFAM), or knockdown of ATP synthase coupling factor 6 (ATPsynCF6) in neurons.21 Neuronal mitochondrial dysfunction, induced using either of these tools, causes reduced adult climbing ability and lifespan, decreased redox potential, as well as reduced numbers of presynaptic mitochondria and active zones.21 Using microarray analysis we found that neuronal mitochondrial dysfunction, induced using either TFAM overexpression or knock-down of ATPsynCF6, alters the expression of hundreds of genes in the late third instar larval CNS.21 Approximately 50% of the genes significantly altered by TFAM overexpression were similarly altered by knock-down of ATPsynCF6. This novel model therefore demonstrates that mitochondrial retrograde signaling is active in the Drosophila CNS. A well-defined role of the mitochondrial retrograde response is to reprogram metabolism to compensate for mitochondrial dysfunction.10 We also found evidence of metabolic adaptation to mitochondrial dysfunction in Drosophila neurons, suggesting a switch to glycolytic metabolism. Increased lactate dehydrogenase expression occurs in our model, in yeast and several other Drosophila models of mitochondrial dysfunction and may thus be a hallmark of the mitochondrial retrograde response.22-25 Increased CNS lactate levels are
associated with mitochondrial diseases such as mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episodes (MELAS) and have been observed in Drosophila parkin mutants and some Parkinson disease patients.26,27 Studies in human cellular models of mitochondrial disease have demonstrated that the transcriptional response elicited by retrograde signaling depends on the severity of mitochondrial dysfunction. The A3243G mutation in the mtDNA tRNALeu gene causes MELAS. Studies using cells containing varying copy numbers of the A3243G mtDNA mutation, or completely lacking mtDNA, have shown that the transcriptional response varies according to the severity of mitochondrial dysfunction, even in the same cell type.28,29 In one study, 4 distinct transcriptional phases were observed according to increasing A3243G mutant mtDNA copy number.29 These studies suggest that the complex nature of mitochondrial diseases may be in part due to differences in retrograde signaling. Activation of the basic helix-loop-helix PAS domain transcription factor hypoxia inducible factor a (HIFa) switches cells to a glycolytic state in hypoxic conditions. The Drosophila HIFa ortholog Similar (Sima), also directly regulates the transcription of several of the retrograde response genes we identified.30,21 To functionally test whether Sima participates in retrograde signaling we performed epistasis experiments. Surprisingly, these experiments showed that neuronal-specific knock-down of sima partially restores the reduced climbing and lifespan phenotypes of TFAM overexpressing flies.21 Similarly, pan-neuronal sima knockdown rescued the defect in neuronal function in a Drosophila model of the mitochondrial disease Leigh
FLY
syndrome (using Surf1 RNAi).21 These data suggest that HIFa is a key regulator of mitochondrial retrograde signaling in the nervous system (Fig. 1). However, they also indicate that, counterintuitively, the retrograde response mediated by HIFa contributes to the pathology caused by mitochondrial dysfunction. A number of other studies in a variety of systems have also shown that inhibition of the mitochondrial retrograde response can reverse pathological phenotypes. In Drosophila, inhibition of retrograde signaling can reverse the cell cycle arrest phenotype caused by mutations in mitochondrial genes. In the developing eye, imaginal disc cells that are mutant for the complex I subunit Pdsw, or the complex IV subunit cytochrome c oxidase Va (CoVa) arrest during the G1/S phase transition.11 These mitochondrial mutations trigger retrograde signaling via either FoxO or p53. Inhibition of retrograde signaling in cells that are double mutant for Pdsw and FoxO, or CoVa and p53, prevents the cell cycle arrest caused by activation of retrograde signaling, allowing cells to re-enter the cell cycle. Mitochondrial dysfunction is also observed in cancerous cells, which accumulate mtDNA mutations31 and express reduced levels of ETC complexes.32 Work from Avadhani’s group using cultured mouse myoblast C2C12 cells has shown that mitochondrial dysfunction, caused by drug-induced mtDNA loss, or uncoupling of the ETC from ATP synthase, causes decreased apoptosis and increased tumor invasiveness in transplant models.16 Loss of mitochondrial membrane potential causes increased cytosolic Ca2C, resulting in activation of calcineurin.33 Calcineurin activates NFkB, which causes nuclear translocation of the REL-p50 heterodimer, where it associates with C/EBPd, CREB and NFAT in a nuclear enhanceosome to regulate gene expression.34 Thus, mitochondrial retrograde signaling can drive tumorigenesis. In this model inhibition of retrograde signaling (by knock-down of IkBb) reduces resistance to apoptosis and decreases the invasive phenotype caused by mitochondrial dysfunction.34 The A1555G mutation in the mtDNA encoded 12S rRNA gene causes nonsyndromic and/or aminoglycoside-induced deafness.35 AMP kinase activation is a key retrograde signal in mammalian cells carrying the mtDNA A1555G mutation.36 In this context mitochondrial dysfunction causes ROS-dependent signaling through AMP kinase and the transcription factor E2F1. Mitochondrial retrograde pathway activation of E2F1 in A1555G mutant cells causes increased
21
sensitivity to apoptosis. However, inhibition of the mitochondrial retrograde response, through loss of the transcription factor E2F1, restores hearing function in a mouse deafness model.36 Thus, inhibition of mitochondrial retrograde signaling may restore cellular homeostasis in a variety of cell and tissue types and is therefore a potential avenue for clinical intervention. The finding that inhibition of retrograde signaling reverses disease phenotypes is somewhat counter-intuitive. We hypothesize that during normal fluctuations in mitochondrial function, resulting from variable oxygen supply or changing nutrient availability, retrograde signaling benefits the cell and organism. The retrograde response promotes the expression of glycolytic genes, which allow cells to compensate for reduced mitochondrial ATP synthesis.21,22,37 Moreover, gene expression analysis in neurons suggests that retrograde signaling inhibits protein translation.21 As translation has the greatest single requirement for ATP, this would also allow cells to cope with mitochondrial dysfunction. By contrast, the permanent mitochondrial damage that occurs in disease models (and potentially in human disease) causes long-term activation of mitochondrial retrograde signaling. We propose that this long-term activation contributes to disease phenotypes. Thus, transient retrograde activation temporally increases cell proliferation, but unchecked activation in cancer cells results in tumorigenesis. In neurons, transient retrograde activation results in a temporary beneficial reduction in translation, but constitutive activation and longterm loss of protein synthesis in neurodegenerative disease contributes to neuronal dysfunction and loss. Similarly, switching to glycolytic metabolism is temporarily beneficial, but long-term dependence on glycolysis and lack of mitochondrial ATP synthesis may contribute to the disease phenotype. This hypothesis may explain the findings from our study and other disease models in which retrograde signaling contributes to the disease phenotype. Furthermore, in our Drosophila model, inhibition of retrograde signaling ameliorates, but does not fully restore neuronal function. We postulate that this is because there is still a mitochondrial deficit, but that the deleterious consequences of constitutive retrograde signaling have been reversed. We showed that HIFa is a key regulator of mitochondrial dysfunction in Drosophila, but the mechanism by which mitochondria regulate HIFa in neurons is currently unknown. During hypoxia HIFa is regulated by the action of oxygen depended prolyl hydroxylases
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(PHDs). In the presence of oxygen PHDs hydroxylate HIFa on specific proline residues that act as recognition sites for the von Hippel-Lindau protein (pVHL) E3 ubiquitin ligase complex, resulting in proteosomal degradation of HIFa. During hypoxia PHD activity is reduced, HIFa is stabilised and translocates to the nucleus where it activates gene transcription. Whether mitochondrial dysfunction in the Drosophila CNS results in ‘pseudohypoxia’ resulting in HIFa stabilization, as observed in cancer cells mutant for components of the tricarboxylic acid (TCA) cycle,38 or whether an alternative mechanism causes HIFa stabilization/activation is not known. Moreover, modulation of HIFa may have different effects depending on the tissue or disease context. A recent study using the Ndufs4 mouse model of the mitochondrial disease Leigh syndrome demonstrates a protective effect of hypoxia.39 In this study the reduced lifespan and locomotor phenotypes of Ndufs4 knockout mice were rescued by exposure to hypoxia. By contrast, in another recent study hypoxia promoted neurodegeneration in photoreceptor neurons in mice.40 Degeneration of neurons in this mouse model could also be triggered by genetically inducing HIFa expression and was rescued by genetic ablation of HIFa in retinal pigment epithelium cells. Clearly, HIFa plays a key role in neurological disease and understanding its contribution to pathology in specific cells and tissues could have important therapeutic potential. In conclusion, the discovery that inhibiting mitochondrial retrograde signaling reverses disease phenotypes suggests that this approach could be used in any number of conditions associated with mitochondrial dysfunction. Further work will be required to elucidate the interplay of these retrograde signals and their exact role in disease. However, the prevalence of mitochondrial dysfunction associated with human disease means that basic studies in Drosophila and other models could have widespread potential applications. It seems that manipulating the retrograde response by blocking the action of key transcription factors may hold potential as a therapeutic strategy to treat disorders caused by mitochondrial dysfunction.
Disclosure of potential conflicts of interest No potential conflicts of interest were disclosed.
Funding This original work described was funded by the Wellcome Trust (WT089622MA), the BBSRC (BB/I012273/1), the
National Institute for Health Research (NIHR), the Biomedical Research Center at King’s College London (KCL), the Edmund J. Safra foundation and KCL. This article presents independent research funded by the NIHR. The views expressed are those of the authors and not necessarily those of the NHS, the NIHR or the Department of Health.
References [1] Iacovino M, Granycome C, Sembongi H, Bokori-Brown M, Butow RA, Holt IJ, Bateman JM. The conserved translocase Tim17 prevents mitochondrial DNA loss. Hum Mol Genet 2009; 18:65-74; PMID:18826960; http://dx. doi.org/10.1093/hmg/ddn313 [2] Schapira AH. Mitochondrial disease. Lancet 2006; 368:70-82; PMID:16815381; http://dx.doi.org/10.1016/ S0140-6736(06)68970-8 [3] Baloyannis SJ, Costa V, Michmizos D. Mitochondrial alterations in Alzheimer’s disease. Am J Alzheimers Dis Other Demen 2004; 19:89-93; PMID:15106389; http://dx. doi.org/10.1177/153331750401900205 [4] Coskun PE, Beal MF, Wallace DC. Alzheimer’s brains harbor somatic mtDNA control-region mutations that suppress mitochondrial transcription and replication. Proc Natl Acad Sci U S A 2004; 101:10726-31; PMID:15247418; http://dx.doi.org/10.1073/pnas.0403649101 [5] Kim SH, Vlkolinsky R, Cairns N, Fountoulakis M, Lubec G. The reduction of NADH ubiquinone oxidoreductase 24- and 75-kDa subunits in brains of patients with Down syndrome and Alzheimer’s disease. Life Sci 2001; 68:2741-50; PMID:11400916; http://dx.doi.org/10.1016/ S0024-3205(01)01074-8 [6] Dexter DT, Carter CJ, Wells FR, Javoy-Agid F, Agid Y, Lees A, Jenner P, Marsden CD. Basal lipid peroxidation in substantia nigra is increased in Parkinson’s disease. J Neurochem 1989; 52:381-9; PMID:2911023; http://dx. doi.org/10.1111/j.1471-4159.1989.tb09133.x [7] Schapira AH, Cooper JM, Dexter D, Jenner P, Clark JB, Marsden CD. Mitochondrial complex I deficiency in Parkinson’s disease. Lancet 1989; 1:1269; PMID:2566813; http://dx.doi.org/10.1016/S0140-6736(89)92366-0 [8] Gatt AP, Duncan OF, Attems J, Francis PT, Ballard CG, Bateman JM. Dementia in Parkinson’s disease is associated with enhanced mitochondrial complex I deficiency. Mov Disord 2016; 31:352-9; PMID:26853899; http://dx. doi.org/10.1002/mds.26513 [9] Gatt AP, Jones EL, Francis PT, Ballard C, Bateman JM. Association of a polymorphism in mitochondrial transcription factor A (TFAM) with Parkinson’s disease dementia but not dementia with Lewy bodies. Neurosci Lett 2013; 557 Pt B:177-80; PMID:24184878; http://dx. doi.org/10.1016/j.neulet.2013.10.045 [10] Butow RA, Avadhani NG. Mitochondrial signaling: the retrograde response. Mol Cell 2004; 14:1-15; PMID:15068799; http://dx.doi.org/10.1016/S1097-2765(04)00179-0 [11] Owusu-Ansah E, Yavari A, Mandal S, Banerjee U. Distinct mitochondrial retrograde signals control the G1-S
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in yeast. Yeast 1999; 15:1377-91; PMID:10509019; http:// dx.doi.org/10.1002/(SICI)1097-0061(19990930) 15:133.0.CO;2-0 Fernandez-Ayala DJ, Chen S, Kemppainen E, O’Dell KM, Jacobs HT. Gene expression in a Drosophila model of mitochondrial disease. PLoS One 2010; 5: e8549; PMID:20066047; http://dx.doi.org/10.1371/ journal.pone.0008549 Freije WA, Mandal S, Banerjee U. Expression profiling of attenuated mitochondrial function identifies retrograde signals in Drosophila. G3 (Bethesda) 2012; 2:843-51; PMID:22908033; http://dx.doi.org/full_text Tufi R, Gandhi S, de Castro IP, Lehmann S, Angelova PR, Dinsdale D, Deas E, Plun-Favreau H, Nicotera P, Abramov AY, et al. Enhancing nucleotide metabolism protects against mitochondrial dysfunction and neurodegeneration in a PINK1 model of Parkinson’s disease. Nat Cell Biol 2014; 16:157-66; PMID:24441527; http://dx.doi.org/ 10.1038/ncb2901 Sproule DM, Kaufmann P. Mitochondrial encephalopathy, lactic acidosis, and strokelike episodes: basic concepts, clinical phenotype, and therapeutic management of MELAS syndrome. Ann New York Acad Sci 2008; 1142:133-58; PMID:18990125; http://dx.doi.org/10.1196/ annals.1444.011 Vincent A, Briggs L, Chatwin GF, Emery E, Tomlins R, Oswald M, Middleton CA, Evans GJ, Sweeney ST, Elliott CJ. parkin-induced defects in neurophysiology and locomotion are generated by metabolic dysfunction and not oxidative stress. Hum Mol Genet 2012; 21:1760-9; PMID:22215442; http://dx.doi.org/10.1093/hmg/ddr609 Jahangir Tafrechi RS, Svensson PJ, Janssen GM, Szuhai K, Maassen JA, Raap AK. Distinct nuclear gene expression profiles in cells with mtDNA depletion and homoplasmic A3243G mutation. Mutat Res 2005; 578:43-52; PMID:16202796; http://dx.doi.org/10.1016/ j.mrfmmm.2005.02.002 Picard M, Zhang J, Hancock S, Derbeneva O, Golhar R, Golik P, O’Hearn S, Levy S, Potluri P, Lvova M, et al. Progressive increase in mtDNA 3243A>G heteroplasmy causes abrupt transcriptional reprogramming. Proc Natl Acad Sci U S A 2014; 111:E4033-42; PMID:25192935; http://dx.doi.org/10.1073/pnas.1414028111 Lavista-Llanos S, Centanin L, Irisarri M, Russo DM, Gleadle JM, Bocca SN, Muzzopappa M, Ratcliffe PJ, Wappner P. Control of the hypoxic response in Drosophila melanogaster by the basic helix-loop-helix PAS protein similar. Mol Cell Biol 2002; 22:6842-53; PMID:12215541; http://dx. doi.org/10.1128/MCB.22.19.6842-6853.2002 Petros JA, Baumann AK, Ruiz-Pesini E, Amin MB, Sun CQ, Hall J, Lim S, Issa MM, Flanders WD, Hosseini SH, et al. mtDNA mutations increase tumorigenicity in prostate cancer. Proc Natl Acad Sci U S A 2005; 102:719-24; PMID:15647368; http://dx.doi.org/ 10.1073/pnas.0408894102 Putignani L, Raffa S, Pescosolido R, Aimati L, Signore F, Torrisi MR, Grammatico P. Alteration of expression
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levels of the oxidative phosphorylation system (OXPHOS) in breast cancer cell mitochondria. Breast Cancer Res Treat 2008; 110:439-52; PMID:17899367; http://dx.doi.org/10.1007/s10549-007-9738-x Amuthan G, Biswas G, Zhang SY, Klein-Szanto A, Vijayasarathy C, Avadhani NG. Mitochondria-tonucleus stress signaling induces phenotypic changes, tumor progression and cell invasion. EMBO J 2001; 20:1910-20; PMID:11296224; http://dx.doi.org/10.1093/ emboj/20.8.1910 Biswas G, Tang W, Sondheimer N, Guha M, Bansal S, Avadhani NG. A distinctive physiological role for IkappaBbeta in the propagation of mitochondrial respiratory stress signaling. J Biol Chem 2008; 283:12586-94; PMID: 18272519; http://dx.doi.org/10.1074/jbc.M710481200 Prezant TR, Agapian JV, Bohlman MC, Bu X, Oztas S, Qiu WQ, Arnos KS, Cortopassi GA, Jaber L, Rotter JI, et al. Mitochondrial ribosomal RNA mutation associated with both antibiotic-induced and non-syndromic deafness. Nat Genet 1993; 4:289-94; PMID:7689389; http:// dx.doi.org/10.1038/ng0793-289 Raimundo N, Song L, Shutt TE, McKay SE, Cotney J, Guan MX, Gilliland TC, Hohuan D, Santos-Sacchi J, Shadel GS. Mitochondrial stress engages E2F1 apoptotic signaling to
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cause deafness. Cell 2012; 148:716-26; PMID:22341444; http://dx.doi.org/10.1016/j.cell.2011.12.027 Srinivasan S, Guha M, Dong DW, Whelan KA, Ruthel G, Uchikado Y, Natsugoe S, Nakagawa H, Avadhani NG. Disruption of cytochrome c oxidase function induces the Warburg effect and metabolic reprogramming. Oncogene 2015; 35:1585-95; PMID:26148236 MacKenzie ED, Selak MA, Tennant DA, Payne LJ, Crosby S, Frederiksen CM, Watson DG, Gottlieb E. Cellpermeating alpha-ketoglutarate derivatives alleviate pseudohypoxia in succinate dehydrogenase-deficient cells. Mol Cell Biol 2007; 27:3282-9; PMID:17325041; http:// dx.doi.org/10.1128/MCB.01927-06 Jain IH, Zazzeron L, Goli R, Alexa K, Schatzman-Bone S, Dhillon H, Goldberger O, Peng J, Shalem O, Sanjana NE, et al. Hypoxia as a therapy for mitochondrial disease. Science (New York, NY) 2016; 352:54-61; PMID:26917594; doi: aad9642 Kurihara T, Westenskow PD, Gantner ML, Usui Y, Schultz A, Bravo S, Aguilar E, Wittgrove C, Friedlander MS, Paris LP, et al. Hypoxia-induced metabolic stress in retinal pigment epithelial cells is sufficient to induce photoreceptor degeneration. eLife 2016; 5; PMID:26978795; http://dx.doi.org/10.7554/eLife.14319
EXTRA VIEW
Mitochondrial retrograde signaling in the Drosophila nervous system and beyond Olivia F. Duncan and Joseph M. Bateman Wolfson Center for Age-Related Diseases, King’s College London, Guy’s Campus, London, UK
ABSTRACT
ARTICLE HISTORY
Mitochondrial dysfunction has been suggested to contribute to neurodegenerative diseases, including Alzheimer and Parkinson disease. Cells respond to changes in the functional state of mitochondria via retrograde signaling pathways from the mitochondria to the nucleus, but little is known about retrograde signaling in the nervous system. We have recently shown that inhibition of retrograde signaling reduces the impact of neuronal mitochondrial dysfunction. We performed a study designed to characterize the mitochondrial retrograde signaling pathway in the Drosophila nervous system. Using several different models we found that neuronal specific mitochondrial dysfunction results in defects in synapse development and neuronal function. Moreover, we identified the Drosophila hypoxia inducible factor a (HIFa) ortholog Sima as a key neuronal transcriptional regulator. Knockdown of sima restores function in several Drosophila models of mitochondrial dysfunction, including models of human disease. Here we discuss these findings and speculate on the potential benefits of inhibition of retrograde signaling. We also describe how our results relate to other studies of mitochondrial retrograde signaling and the potential therapeutic applications of these discoveries.
Received 20 January 2016 Revised 24 March 2016 Accepted 30 March 2016
Mitochondria produce the majority of cellular energy in the form of ATP and play key roles in amino acid synthesis, calcium buffering, iron-sulfur cluster synthesis, generation of reactive oxygen species (ROS) and apoptosis. Dysfunction of this multifunctional organelle is associated with a wide range of disorders, from diabetes to cancer and neurodegeneration.1,2 The high metabolic demand of the nervous system makes it particularly sensitive to mitochondrial deficits. Altered mitochondrial morphology, decreased complex I activity and reduced mitochondrial DNA (mtDNA) levels are observed in the cortex of Alzheimer disease (AD) patients.3-5 Complex I deficiencies and increased production of ROS are also detected in the substantia nigra pars compacta in Parkinson disease patients.6,7 Similarly, complex I deficiency and mtDNA loss are observed in the prefrontal cortex of patients with Parkinson disease dementia.8,9 The mitochondrial retrograde response is a signaling pathway that enables cells to respond to changes in the functional state of mitochondria. Mitochondrial retrograde signaling is a pathway of communication from mitochondria to the nucleus, resulting in changes in
KEYWORDS
Drosophila; HIFa; Mitochondria; neuron; neurodegeneration; retrograde signaling
nuclear gene expression (Fig. 1).10 This is opposite to anterograde signaling from the nucleus to mitochondria. Retrograde signaling varies according to the context, ranging from cellular metabolic changes to cell cycle arrest and even modification of the systemic integrated stress response.10-12 Retrograde signaling has been well characterized in budding yeast and has been linked to the mechanistic target of rapamycin (mTOR) pathway in this model.13 In yeast, reduced glutamine levels activate the retrograde response,14 resulting in nuclear translocation of the Rtg1/Rtg3 transcriptional heterodimer.15 Activation of retrograde signaling can result from changes in cellular metabolic status, AMP: ATP ratio, ROS levels, Ca2C concentration, or compromised mitochondrial membrane potential.10,16-18 A number of different mitochondrial retrograde signaling pathways have been identified in mammalian cells. For example, increased cytosolic Ca2C concentration activates cAMP-responsive element-binding protein (CREB), triggering a transcriptional response.19 Other pathways such as mTOR, NFkB and Sirt1 are also implicated in the mammalian retrograde response.20 These studies have focused on proliferating cells and it
CONTACT Joseph M. Bateman [email protected] Wolfson Center for Age-Related Diseases, King’s College London, Guy’s Campus, London SE1 1UL, UK. Color versions of one or more of the figures in the article can be found online at www.tandfonline.com/kfly © 2016 Taylor & Francis
20
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Figure 1. A model for neuronal mitochondrial retrograde signaling in Drosophila. Mitochondrial dysfunction causes reduced mitochondrial membrane potential (DC) and triggers the retrograde response. In the Drosophila nervous system HIFa (Sima) regulates retrograde response genes to reprogram neurons by changing the metabolic state of the cell and inhibiting protein translation.
is unclear how relevant these pathways are to mitochondrial retrograde signaling in post-mitotic neurons. To address this we recently developed a model to investigate the mitochondrial retrograde response in the Drosophila central nervous system (CNS). We characterized the transcriptional response to mitochondrial dysfunction caused either by overexpression of mitochondrial transcription factor A (TFAM), or knockdown of ATP synthase coupling factor 6 (ATPsynCF6) in neurons.21 Neuronal mitochondrial dysfunction, induced using either of these tools, causes reduced adult climbing ability and lifespan, decreased redox potential, as well as reduced numbers of presynaptic mitochondria and active zones.21 Using microarray analysis we found that neuronal mitochondrial dysfunction, induced using either TFAM overexpression or knock-down of ATPsynCF6, alters the expression of hundreds of genes in the late third instar larval CNS.21 Approximately 50% of the genes significantly altered by TFAM overexpression were similarly altered by knock-down of ATPsynCF6. This novel model therefore demonstrates that mitochondrial retrograde signaling is active in the Drosophila CNS. A well-defined role of the mitochondrial retrograde response is to reprogram metabolism to compensate for mitochondrial dysfunction.10 We also found evidence of metabolic adaptation to mitochondrial dysfunction in Drosophila neurons, suggesting a switch to glycolytic metabolism. Increased lactate dehydrogenase expression occurs in our model, in yeast and several other Drosophila models of mitochondrial dysfunction and may thus be a hallmark of the mitochondrial retrograde response.22-25 Increased CNS lactate levels are
associated with mitochondrial diseases such as mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episodes (MELAS) and have been observed in Drosophila parkin mutants and some Parkinson disease patients.26,27 Studies in human cellular models of mitochondrial disease have demonstrated that the transcriptional response elicited by retrograde signaling depends on the severity of mitochondrial dysfunction. The A3243G mutation in the mtDNA tRNALeu gene causes MELAS. Studies using cells containing varying copy numbers of the A3243G mtDNA mutation, or completely lacking mtDNA, have shown that the transcriptional response varies according to the severity of mitochondrial dysfunction, even in the same cell type.28,29 In one study, 4 distinct transcriptional phases were observed according to increasing A3243G mutant mtDNA copy number.29 These studies suggest that the complex nature of mitochondrial diseases may be in part due to differences in retrograde signaling. Activation of the basic helix-loop-helix PAS domain transcription factor hypoxia inducible factor a (HIFa) switches cells to a glycolytic state in hypoxic conditions. The Drosophila HIFa ortholog Similar (Sima), also directly regulates the transcription of several of the retrograde response genes we identified.30,21 To functionally test whether Sima participates in retrograde signaling we performed epistasis experiments. Surprisingly, these experiments showed that neuronal-specific knock-down of sima partially restores the reduced climbing and lifespan phenotypes of TFAM overexpressing flies.21 Similarly, pan-neuronal sima knockdown rescued the defect in neuronal function in a Drosophila model of the mitochondrial disease Leigh
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syndrome (using Surf1 RNAi).21 These data suggest that HIFa is a key regulator of mitochondrial retrograde signaling in the nervous system (Fig. 1). However, they also indicate that, counterintuitively, the retrograde response mediated by HIFa contributes to the pathology caused by mitochondrial dysfunction. A number of other studies in a variety of systems have also shown that inhibition of the mitochondrial retrograde response can reverse pathological phenotypes. In Drosophila, inhibition of retrograde signaling can reverse the cell cycle arrest phenotype caused by mutations in mitochondrial genes. In the developing eye, imaginal disc cells that are mutant for the complex I subunit Pdsw, or the complex IV subunit cytochrome c oxidase Va (CoVa) arrest during the G1/S phase transition.11 These mitochondrial mutations trigger retrograde signaling via either FoxO or p53. Inhibition of retrograde signaling in cells that are double mutant for Pdsw and FoxO, or CoVa and p53, prevents the cell cycle arrest caused by activation of retrograde signaling, allowing cells to re-enter the cell cycle. Mitochondrial dysfunction is also observed in cancerous cells, which accumulate mtDNA mutations31 and express reduced levels of ETC complexes.32 Work from Avadhani’s group using cultured mouse myoblast C2C12 cells has shown that mitochondrial dysfunction, caused by drug-induced mtDNA loss, or uncoupling of the ETC from ATP synthase, causes decreased apoptosis and increased tumor invasiveness in transplant models.16 Loss of mitochondrial membrane potential causes increased cytosolic Ca2C, resulting in activation of calcineurin.33 Calcineurin activates NFkB, which causes nuclear translocation of the REL-p50 heterodimer, where it associates with C/EBPd, CREB and NFAT in a nuclear enhanceosome to regulate gene expression.34 Thus, mitochondrial retrograde signaling can drive tumorigenesis. In this model inhibition of retrograde signaling (by knock-down of IkBb) reduces resistance to apoptosis and decreases the invasive phenotype caused by mitochondrial dysfunction.34 The A1555G mutation in the mtDNA encoded 12S rRNA gene causes nonsyndromic and/or aminoglycoside-induced deafness.35 AMP kinase activation is a key retrograde signal in mammalian cells carrying the mtDNA A1555G mutation.36 In this context mitochondrial dysfunction causes ROS-dependent signaling through AMP kinase and the transcription factor E2F1. Mitochondrial retrograde pathway activation of E2F1 in A1555G mutant cells causes increased
21
sensitivity to apoptosis. However, inhibition of the mitochondrial retrograde response, through loss of the transcription factor E2F1, restores hearing function in a mouse deafness model.36 Thus, inhibition of mitochondrial retrograde signaling may restore cellular homeostasis in a variety of cell and tissue types and is therefore a potential avenue for clinical intervention. The finding that inhibition of retrograde signaling reverses disease phenotypes is somewhat counter-intuitive. We hypothesize that during normal fluctuations in mitochondrial function, resulting from variable oxygen supply or changing nutrient availability, retrograde signaling benefits the cell and organism. The retrograde response promotes the expression of glycolytic genes, which allow cells to compensate for reduced mitochondrial ATP synthesis.21,22,37 Moreover, gene expression analysis in neurons suggests that retrograde signaling inhibits protein translation.21 As translation has the greatest single requirement for ATP, this would also allow cells to cope with mitochondrial dysfunction. By contrast, the permanent mitochondrial damage that occurs in disease models (and potentially in human disease) causes long-term activation of mitochondrial retrograde signaling. We propose that this long-term activation contributes to disease phenotypes. Thus, transient retrograde activation temporally increases cell proliferation, but unchecked activation in cancer cells results in tumorigenesis. In neurons, transient retrograde activation results in a temporary beneficial reduction in translation, but constitutive activation and longterm loss of protein synthesis in neurodegenerative disease contributes to neuronal dysfunction and loss. Similarly, switching to glycolytic metabolism is temporarily beneficial, but long-term dependence on glycolysis and lack of mitochondrial ATP synthesis may contribute to the disease phenotype. This hypothesis may explain the findings from our study and other disease models in which retrograde signaling contributes to the disease phenotype. Furthermore, in our Drosophila model, inhibition of retrograde signaling ameliorates, but does not fully restore neuronal function. We postulate that this is because there is still a mitochondrial deficit, but that the deleterious consequences of constitutive retrograde signaling have been reversed. We showed that HIFa is a key regulator of mitochondrial dysfunction in Drosophila, but the mechanism by which mitochondria regulate HIFa in neurons is currently unknown. During hypoxia HIFa is regulated by the action of oxygen depended prolyl hydroxylases
22
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(PHDs). In the presence of oxygen PHDs hydroxylate HIFa on specific proline residues that act as recognition sites for the von Hippel-Lindau protein (pVHL) E3 ubiquitin ligase complex, resulting in proteosomal degradation of HIFa. During hypoxia PHD activity is reduced, HIFa is stabilised and translocates to the nucleus where it activates gene transcription. Whether mitochondrial dysfunction in the Drosophila CNS results in ‘pseudohypoxia’ resulting in HIFa stabilization, as observed in cancer cells mutant for components of the tricarboxylic acid (TCA) cycle,38 or whether an alternative mechanism causes HIFa stabilization/activation is not known. Moreover, modulation of HIFa may have different effects depending on the tissue or disease context. A recent study using the Ndufs4 mouse model of the mitochondrial disease Leigh syndrome demonstrates a protective effect of hypoxia.39 In this study the reduced lifespan and locomotor phenotypes of Ndufs4 knockout mice were rescued by exposure to hypoxia. By contrast, in another recent study hypoxia promoted neurodegeneration in photoreceptor neurons in mice.40 Degeneration of neurons in this mouse model could also be triggered by genetically inducing HIFa expression and was rescued by genetic ablation of HIFa in retinal pigment epithelium cells. Clearly, HIFa plays a key role in neurological disease and understanding its contribution to pathology in specific cells and tissues could have important therapeutic potential. In conclusion, the discovery that inhibiting mitochondrial retrograde signaling reverses disease phenotypes suggests that this approach could be used in any number of conditions associated with mitochondrial dysfunction. Further work will be required to elucidate the interplay of these retrograde signals and their exact role in disease. However, the prevalence of mitochondrial dysfunction associated with human disease means that basic studies in Drosophila and other models could have widespread potential applications. It seems that manipulating the retrograde response by blocking the action of key transcription factors may hold potential as a therapeutic strategy to treat disorders caused by mitochondrial dysfunction.
Disclosure of potential conflicts of interest No potential conflicts of interest were disclosed.
Funding This original work described was funded by the Wellcome Trust (WT089622MA), the BBSRC (BB/I012273/1), the
National Institute for Health Research (NIHR), the Biomedical Research Center at King’s College London (KCL), the Edmund J. Safra foundation and KCL. This article presents independent research funded by the NIHR. The views expressed are those of the authors and not necessarily those of the NHS, the NIHR or the Department of Health.
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