Refine
Has Fulltext
- yes (29)
Is part of the Bibliography
- yes (29) (remove)
Year of publication
Document Type
- Journal article (19)
- Doctoral Thesis (8)
- Preprint (2)
Keywords
- mitochondria (29) (remove)
Institute
- Theodor-Boveri-Institut für Biowissenschaften (12)
- Deutsches Zentrum für Herzinsuffizienz (DZHI) (6)
- Institut für Anatomie und Zellbiologie (2)
- Institut für Virologie und Immunbiologie (2)
- Julius-von-Sachs-Institut für Biowissenschaften (2)
- Lehrstuhl für Biochemie (2)
- Neurologische Klinik und Poliklinik (2)
- Comprehensive Cancer Center Mainfranken (1)
- Graduate School of Life Sciences (1)
- Institut für Hygiene und Mikrobiologie (1)
Metabolic Alterations Caused by Defective Cardiolipin Remodeling in Inherited Cardiomyopathies
(2020)
The heart is the most energy-consuming organ in the human body. In heart failure, the homeostasis of energy supply and demand is endangered by an increase in cardiomyocyte workload, or by an insufficiency in energy-providing processes. Energy metabolism is directly associated with mitochondrial redox homeostasis. The production of toxic reactive oxygen species (ROS) may overwhelm mitochondrial and cellular ROS defense mechanisms in case of heart failure. Mitochondria are essential cell organelles and provide 95% of the required energy in the heart. Metabolic remodeling, changes in mitochondrial structure or function, and alterations in mitochondrial calcium signaling diminish mitochondrial energy provision in many forms of cardiomyopathy. The mitochondrial respiratory chain creates a proton gradient across the inner mitochondrial membrane, which couples respiration with oxidative phosphorylation and the preservation of energy in the chemical bonds of ATP. Akin to other mitochondrial enzymes, the respiratory chain is integrated into the inner mitochondrial membrane. The tight association with the mitochondrial phospholipid cardiolipin (CL) ensures its structural integrity and coordinates enzymatic activity. This review focuses on how changes in mitochondrial CL may be associated with heart failure. Dysfunctional CL has been found in diabetic cardiomyopathy, ischemia reperfusion injury and the aging heart. Barth syndrome (BTHS) is caused by an inherited defect in the biosynthesis of cardiolipin. Moreover, a dysfunctional CL pool causes other types of rare inherited cardiomyopathies, such as Sengers syndrome and Dilated Cardiomyopathy with Ataxia (DCMA). Here we review the impact of cardiolipin deficiency on mitochondrial functions in cellular and animal models. We describe the molecular mechanisms concerning mitochondrial dysfunction as an incitement of cardiomyopathy and discuss potential therapeutic strategies.
In heart failure, a functional block of complex I of the respiratory chain provokes superoxide generation, which is transformed to H\(_2\)O\(_2\) by dismutation. The Krebs cycle produces NADH, which delivers electrons to complex I, and NADPH for H\(_2\)O\(_2\) elimination via isocitrate dehydrogenase and nicotinamide nucleotide transhydrogenase (NNT). At high NADH levels, α-ketoglutarate dehydrogenase (α-KGDH) is a major source of superoxide in skeletal muscle mitochondria with low NNT activity. Here, we analyzed how α-KGDH and NNT control H\(_2\)O\(_2\) emission in cardiac mitochondria. In cardiac mitochondria from NNT-competent BL/6N mice, H\(_2\)O\(_2\) emission is equally low with pyruvate/malate (P/M) or α-ketoglutarate (α-KG) as substrates. Complex I inhibition with rotenone increases H2O2 emission from P/M, but not α-KG respiring mitochondria, which is potentiated by depleting H\(_2\)O\(_2\)-eliminating capacity. Conversely, in NNT-deficient BL/6J mitochondria, H2O2 emission is higher with α-KG than with P/M as substrate, and further potentiated by complex I blockade. Prior depletion of H\(_2\)O\(_2\)-eliminating capacity increases H\(_2\)O\(_2\) emission from P/M, but not α-KG respiring mitochondria. In cardiac myocytes, downregulation of α-KGDH activity impaired dynamic mitochondrial redox adaptation during workload transitions, without increasing H\(_2\)O\(_2\) emission. In conclusion, NADH from α-KGDH selectively shuttles to NNT for NADPH formation rather than to complex I of the respiratory chain for ATP production. Therefore, α-KGDH plays a key role for H\(_2\)O\(_2\) elimination, but is not a relevant source of superoxide in heart. In heart failure, α-KGDH/NNT-dependent NADPH formation ameliorates oxidative stress imposed by complex I blockade. Downregulation of α-KGDH may, therefore, predispose to oxidative stress in heart failure.
Bei einer Vielzahl neuromuskulärer und neurodegenerativer Erkrankungen spielen Fehlfunktionen der Mitochondrien eine wichtige Rolle. Da die Proteine der Atmungsketten-komplexe sowohl durch die mitochondriale DNA als auch durch das Kerngenom codiert werden, können Mutationen in beiden Genomen die Auslöser dieser Erkrankungen darstellen. Veränderungen der mitochondrialen DNA lassen sich - im Gegensatz zum Kerngenom - bisher nicht korrigieren, weshalb bei einem großen Teil der Erkrankungen nur die Symptome und nicht die Auslöser behandelt werden können. Das grundlegende Problem stellt dabei der Transport der DNA in die Mitochondrien dar. Ziel dieser Arbeit war es, mit Hilfe von physikalischen Transfektionsmethoden exogene DNA in die Mitochondrien menschlicher Kulturzellen einzubringen. Dazu wurden unterschiedliche Vektoren hergestellt, die in Mitochondrien das an die Mitochondrien angepasste grün fluoreszierende mtEGFP exprimieren sollen. Die Expressionsfähigkeit und Prozessierung dieser Konstrukte konnte in in-vitro-Assays mit einem Mitochondrienextrakt nachgewiesen werden. Bei Transfektionsversuchen mit der Gene Gun gelang es erstmals, exogene Plasmid-DNA in die Mitochondrien menschlicher Zellen einzubringen. Das durch die transfizierten Vektoren exprimierte mtEGFP konnte am Fluoreszenzmikroskop eindeutig in den Mitochondrien der Zellen lokalisiert werden. Eine Transfektion mit Hilfe magnetischer Partikel erwies sich jedoch nicht als zielführend, da die die Partikel eine Eigenfluoreszenz aufwiesen, die eine Detektion der mtEGFP-Expression verhinderten. Eine wichtige Voraussetzung für die Transfektion von Mitochondrien durch mechanische Methoden wie die Mikroinjektion ist die reversible Induktion von Megamitochondrien, da sie erst in diesem Zustand penetriert werden können. Durch eine Ansäuerung des Kulturmediums mit Natriumacetat bzw. Essigsäure konnten Mitochondrien erzeugt werden, die beinahe die Größe des Zellkerns aufwiesen und somit ideale Bedingungen für die Mikroinjektion darstellen. Bei den anschließenden Mikroinjektionsversuchen mit den hergestellten mitochondrialen Expressionsvektoren wurden wiederum Zellen mit eindeutig grün fluoreszierenden Mitochondrien gefunden. Zusammenfassend wurden im Rahmen dieser Arbeit erstmalig menschliche Mitochondrien mit exogener DNA transfiziert. Dies stellt einen grundlegenden Schritt für die Entwicklung neuer Therapieformen bei mitochondrialen Myopathien dar. Zuvor müssen die Transfektionsmethoden jedoch noch weiter optimiert werden, um eine höhere Transfektionseffizienz zu erreichen.
Purpose of Review
We review therapeutic approaches aimed at restoring function of the failing heart by targeting mitochondrial reactive oxygen species (ROS), ion handling, and substrate utilization for adenosine triphosphate (ATP) production.
Recent Findings
Mitochondria-targeted therapies have been tested in animal models of and humans with heart failure (HF). Cardiac benefits of sodium/glucose cotransporter 2 inhibitors might be partly explained by their effects on ion handling and metabolism of cardiac myocytes.
Summary
The large energy requirements of the heart are met by oxidative phosphorylation in mitochondria, which is tightly regulated by the turnover of ATP that fuels cardiac contraction and relaxation. In heart failure (HF), this mechano-energetic coupling is disrupted, leading to bioenergetic mismatch and production of ROS that drive the progression of cardiac dysfunction. Furthermore, HF is accompanied by changes in substrate uptake and oxidation that are considered detrimental for mitochondrial oxidative metabolism and negatively affect cardiac efficiency. Mitochondria lie at the crossroads of metabolic and energetic dysfunction in HF and represent ideal therapeutic targets.
Mitochondrien verändern dynamisch durch ein balanciertes Verhältnis von Teilung und Fusion die Gestalt ihrer Netzwerke und reagieren so auf interne und externe Signale. Ein Schlülsselprotein der mitochondrialen Teilung ist die Dynamin-verwandte GTPase Dnm1p, die in dieser Arbeit charakterisiert wurde. Da Mitochondrien aufgrund ihres endosymbiontischen Ursprungs zwei Membranen besitzen, erfordert deren Teilung eine besondere Koordination. Unter Verwendung von photokonvertierbarem GFP wird in dieser Arbeit gezeigt, dass in S. cerevisiae die Teilung der inneren und äußeren Membran zeitlich eng gekoppelt verläuft. Dieser Prozess wird durch die GTPase Dnm1p, aber auch durch die Adaptor-Proteine Mdv1p und Caf4p sowie dem integralen Membrananker Fis1p v ermittelt. Dnm1p lagert sich zu Spiralen um den tubulären Strang an und trennt GTP-abhängig die Mitochondrien voneinander. Eine Voraussetzung für die Anlagerung dieser Spiralen stellen Matrix-Konstriktionen dar. In dieser Arbeit wird gezeigt, dass Dnm1p und auch Fis1p für die Ausbildung dieser mitochondrialen Einschnürungen nicht essentiell sind. Die Untersuchung der Verteilung, Orientierung und Größe der Epitop-markierten Dnm1p-Cluster bildet den Schwerpunkt der Arbeit. Weiterhin wird der Einfluss der Teilungsproteine Fis1p, Mdv1p und Caf4p auf diese Dnm1p-Charakteristika ermittelt. Die Analyse basiert auf quantitativen Konfokalmikroskopie-Aufnahmen, zusätzlich werden auch neue hochauflösende Lichtmikroskope (4Pi und STED) zur genauen Lokalisation und Größenbestimmung eingesetzt. Die Ergebnisse zeigen, dass im Wildtyp und in Mdv1p-Deletionsstämmen die Mehrheit der Cluster mit den Mitochondrien assoziiert ist, während in Fis1p- und Caf4p-Deletionszellen die Rekrutierung der Cluster zu den Mitochondrien gestört erscheint. Nur wenige Cluster bilden Spiralen um Matrix-Konstriktionen aus, die überwiegende Mehrheit der nicht an aktuellen Teilungsprozessen beteiligten Dnm1p-Aggregate weist dagegen im Wildtyp und in Mdv1p-Deletionszellen eine polare Orientierung Richtung Zellcortex auf. Die in dieser Arbeit zum ersten Mal beschriebene Polarität ist in Fis1p- und Caf4p-Deletionsstämmen aufgehoben, bleibt jedoch auch nach der Zerstörung des Aktin-Gerüstes aufrechterhalten. Die Ergebnisse der Arbeit deuten darauf hin, dass Dnm1p in einem Komplex mit Fis1p und Caf4p zusätzlich zu seiner Funktion als Teilungsprotein an der Anheftung der Mitochondrien an den Zellcortex beteiligt ist. Zudem scheinen die Adaptorproteine Mdv1p und Caf4p trotz molekularer Ähnlichkeit unterschiedliche Aufgaben in der Zelle zu erfüllen.
The normal function of the heart relies on a series of complex metabolic processes orchestrating the proper generation and use of energy. In this context, mitochondria serve a crucial role as a platform for energy transduction by supplying ATP to the varying demand of cardiomyocytes, involving an intricate network of pathways regulating the metabolic flux of substrates. The failure of these processes results in structural and functional deficiencies of the cardiac muscle, including inherited cardiomyopathies. These genetic diseases are characterized by cardiac structural and functional anomalies in the absence of abnormal conditions that can explain the observed myocardial abnormality, and are frequently associated with heart failure. Since their original description, major advances have been achieved in the genetic and phenotype knowledge, highlighting the involvement of metabolic abnormalities in their pathogenesis. This review provides a brief overview of the role of mitochondria in the energy metabolism in the heart and focuses on metabolic abnormalities, mitochondrial dysfunction, and storage diseases associated with inherited cardiomyopathies.
The host's defense against invasive mold infections relies on diverse antimicrobial activities of innate immune cells. However, studying these mechanisms in vitro is complicated by the filamentous nature of such pathogens that typically form long, branched, multinucleated and compartmentalized hyphae. Here we describe a novel method that allows for the visualization and quantification of the antifungal killing activity exerted by human granulocytes against hyphae of the opportunistic pathogen Aspergillus fumigatus. The approach relies on the distinct impact of fungal cell death on the morphology of mitochondria that were visualized with green fluorescent protein (GFP). We show that oxidative stress induces complete fragmentation of the tubular mitochondrial network which correlates with cell death of affected hyphae. Live cell microscopy revealed a similar and non-reversible disruption of the mitochondrial morphology followed by fading of fluorescence in Aspergillus hyphae that were killed by human granulocytes. Quantitative microscopic analysis of fixed samples was subsequently used to estimate the antifungal activity. By utilizing this assay, we demonstrate that lipopolysaccharides as well as human serum significantly increase the killing efficacy of the granulocytes. Our results demonstrate that evaluation of the mitochondrial morphology can be utilized to assess the fungicidal activity of granulocytes against A. fumigatus hyphae.
Background
Multiple sclerosis (MS) is an autoimmune disease of the central nervous system (CNS) characterized by inflammation, demyelination and axonal pathology. Myelin basic protein/proteolipid protein (MBP-PLP) fusion protein MP4 is capable of inducing chronic experimental autoimmune encephalomyelitis (EAE) in susceptible mouse strains mirroring diverse histopathological and immunological hallmarks of MS. Limited availability of human tissue underscores the importance of animal models to study the pathology of MS.
Methods
Twenty-two female C57BL/6 (B6) mice were immunized with MP4 and the clinical development of experimental autoimmune encephalomyelitis (EAE) was observed. Methylene blue-stained semi-thin and ultra-thin sections of the lumbar spinal cord were assessed at the peak of acute EAE, three months (chronic EAE) and six months after onset of EAE (long-term EAE). The extent of lesional area and inflammation were analyzed in semi-thin sections on a light microscopic level. The magnitude of demyelination and axonal damage were determined using electron microscopy. Emphasis was put on the ventrolateral tract (VLT) of the spinal cord.
Results
B6 mice demonstrated increasing demyelination and severe axonal pathology in the course of MP4-induced EAE. In addition, mitochondrial swelling and a decrease in the nearest neighbor neurofilament distance (NNND) as early signs of axonal damage were evident with the onset of EAE. In semi-thin sections we observed the maximum of lesional area in the chronic state of EAE while inflammation was found to a similar extent in acute and chronic EAE. In contrast to the well-established myelin oligodendrocyte glycoprotein (MOG) model, disease stages of MP4-induced EAE could not be distinguished by assessing the extent of parenchymal edema or the grade of inflammation.
Conclusions
Our results complement our previous ultrastructural studies of B6 EAE models and suggest that B6 mice immunized with different antigens constitute useful instruments to study the diverse histopathological aspects of MS.
The control of energy homeostasis is of pivotal importance for all living organisms. In the last years emerged the idea that many stress responses that are apparently unrelated, are actually united by a common increase of the cellular energy demand. Therefore, the so called energy signaling is activated by many kind of stresses and is responsible for the activation of the general stress response. In Arabidopsis thaliana the protein family SnF1- related protein kinases (SnRK1) is involved in the regulation of many physiological processes but is more known for its involvement in the regulation of the energy homeostasis in response to various stresses. To the SnRK1 protein family belong SnRK1.1 (also known as KIN10), SnRK1.2 (KIN11), and SnRK1.3 (KIN12). SnRK1 exerts its function regulating directly the activity of metabolic enzymes or those of key transcription factors (TFs). The only TFs regulated by SnRK1 identified so far is the basic leucine zipper (bZIP) 63. bZIP63 belongs to the C group of bZIPs (C-bZIPs) protein family together with bZIP9, bZIP10, and bZIP25. SnRK1.1 phosphorylates bZIP63 on three amino acids residues, serine (S) 29, S294, and S300. The phosphorylation of tbZIP63 is strongly related to the energy status of the plant, shifting from almost absent during the normal growth to strongly phosphorylated when the plant is exposed to extended dark. bZIPs normally bind the DNA as dimer in order to regulate the expression of their target genes. C-bZIPs preferentially form dimers with S1-bZIPs, constituting the so called C/S1- bZIPs network. The SnRk1 dependent phosphorylation of bZIP63 regulates its activation potential and its dimerization properties. In particular bZIP63 shift its dimerization preferences according to its phosphorylation status. The non-phosphorylated form of bZIP63 dimerize bZIP1, the phosphorylates ones, instead, forms dimer with bZIP1, bZIP11, and bZIP63 its self. Together with bZIP63, S1-bZIPs are important mediator of part of the huge transcriptional reprogramming induced by SnRK1 in response to extended dark. S1-bZIPs regulate, indeed, the expression of 4'000 of the 10'000 SnRK1-regulated genes in response to energy deprivation. In particular S1-bZIPs are very important for the regulation of many genes encoding for enzymes involved in the amino acid metabolism and for their use as alternative energy source. After the exposition for some hours to extended dark, indeed, the plant make use of every energy substrate and amino acids are considered an important energy source together with lipids and proteins. Interestingly, S1- bZIPs regulate the expression of ETFQO. ETFQO is a unique protein that convoglia the electrons provenienti from the branch chain amino acids catabolism into the mitochondrial electron transport chain. The dimer formed between bZIP63 and bZIP2 recruits SnRK1.1 directly on the chromatin of ETFQO promoter. The recruitment of SnRK1 on ETFQO promoter is associated with its acetylation on the lysine 14 of the histone protein 3 (K14H3). This chromatin modification is normally asociated with an euchromatic status of the DNA and therefore with its transcriptional activation. Beside the particular case of the regulation of ETFQO gene, S1-bZIPs are involved in the regulation of many other genes activated in response of different stresses. bZIP1 is for example an important mediator of the salt stress response. In particular bZIP1 regulates the primary C- and N-metabolism. The expression of bZIP1, in response of both salt ans energy stress seems to be regulated by SnRK1, as it is the expression of bZIP53 and bZIP63.
Beside its involvement in the regulation of the energy stress response and salt response, SnRK1 is the primary activators of the lipids metabolism during see germination. SnRK1, indeed, controls the expression of CALEOSINs and OLEOSINs. Those proteins are very important for lipids remobilization from oil droplets. Without their expression seed germination and subsequent establishment do not take place because of the absence of fuel to sustain these highly energy costly processes, which entirely depend on the catabolism of seed storages.
The main goal of the present study was the identification of cellular phenotypes in attention-deficit-/hyperactivity disorder (ADHD) patient-derived cellular models from carriers of rare copy number variants (CNVs) in the PARK2 locus that have been previously associated with ADHD. Human-derived fibroblasts (HDF) were cultured and human-induced pluripotent stem cells (hiPSC) were reprogrammed and differentiated into dopaminergic neuronal cells (mDANs). A series of assays in baseline condition and in different stress paradigms (nutrient deprivation, carbonyl cyanide m-chlorophenyl hydrazine (CCCP)) focusing on mitochondrial function and energy metabolism (ATP production, basal oxygen consumption rates, reactive oxygen species (ROS) abundance) were performed and changes in mitochondrial network morphology evaluated. We found changes in PARK2 CNV deletion and duplication carriers with ADHD in PARK2 gene and protein expression, ATP production and basal oxygen consumption rates compared to healthy and ADHD wildtype control cell lines, partly differing between HDF and mDANs and to some extent enhanced in stress paradigms. The generation of ROS was not influenced by the genotype. Our preliminary work suggests an energy impairment in HDF and mDAN cells of PARK2 CNV deletion and duplication carriers with ADHD. The energy impairment could be associated with the role of PARK2 dysregulation in mitochondrial dynamics.
Mitochondria are organelles of endosymbiotic origin, which play many important roles in eukaryotic cells. Mitochondria are surrounded by two membranes and, considering that most of the mitochondrial proteins are produced in the cytosol, possess import machineries, which transport mitochondria-targeted proteins to their designated location. A special class of outer mitochondrial membrane (OMM) proteins, the β-barrel proteins, require the sorting and assembly machinery (SAM) for their OMM integration. Both mitochondrial β-barrel proteins and the central component of the SAM complex, Sam50, have homologs in gram-negative bacteria. In yeast mitochondria, bacterial β-barrel proteins can be imported and assembled into the OMM. Our group demonstrated that this, however, is not the case for human mitochondria, which import only neisserial β barrel proteins, but not those of Escherichia coli and Salmonella enterica. As a part of this study, I could demonstrate that β-barrel proteins such as Omp85 and PorB of different Neisseria species are targeted to human mitochondria. Interestingly, only proteins belonging to the neisserial Omp85 family were integrated into the OMM, whereas PorB was imported into mitochondria but not assembled. By exchanging parts of homologous neisserial Omp85 and E. coli BamA and, similarly, of neisserial PorB and E. coli OmpC, it could be demonstrated in this work that the mitochondrial import signal of bacterial β barrel proteins cannot be limited to one short linear sequence, but rather secondary structure and protein charge seem to play an important role, as well as specific residues in the last β-strand of Omp85. Omp85 possesses five conserved POTRA domains in its amino-terminal part. This work additionally demonstrated that in human mitochondria, at least two POTRA domains of Omp85 are necessary for membrane integration and functionality of Omp85. In the second part of this work, the influence of Sam50 on the mitochondrial cristae structure was investigated. This work contributed to a study performed by our group in which it was confirmed that Sam50 is present in a high molecular weight complex together with mitofilin, CHCHD3, CHCHD6, DnaJC11, metaxin 1 and metaxin 2. This connection between the inner and outer mitochondrial membrane was shown to be crucial for the maintenance of the mitochondrial cristae structure. In addition, a role of Sam50 in respiratory complex assembly, suggested by a SILAC experiment conducted in our group, could be confirmed by in vitro import studies. An influence of Sam50 not only on respiratory complexes but also on the recently described respiratory complex assembly factor TTC19 was demonstrated. It was shown that TTC19 not only plays a role in complex III assembly as published, but also influences the assembly of respiratory complex IV. Thus, in this part of the work a connection between the OMM protein Sam50 and maintenance of cristae structure, respiratory complex assembly and an assembly factor could be established.
Detailed Analysis of the Human Mitochondrial Contact Site Complex Indicate a Hierarchy of Subunits
(2015)
Mitochondrial inner membrane folds into cristae, which significantly increase its surface and are important for mitochondrial function. The stability of cristae depends on the mitochondrial contact site (MICOS) complex. In human mitochondria, the inner membrane MICOS complex interacts with the outer membrane sorting and assembly machinery (SAM) complex, to form the mitochondrial intermembrane space bridging complex (MIB). We have created knockdown cell lines of most of the MICOS and MIB components and have used them to study the importance of the individual subunits for the cristae formation and complex stability. We show that the most important subunits of the MIB complex in human mitochondria are Mic60/Mitofilin, Mic19/CHCHD3 and an outer membrane component Sam50. We provide additional proof that ApoO indeed is a subunit of the MICOS and MIB complexes and propose the name Mic23 for this protein. According to our results, Mic25/CHCHD6, Mic27/ApoOL and Mic23/ApoO appear to be periphery subunits of the MICOS complex, because their depletion does not affect cristae morphology or stability of other components.
The ganglioside-induced differentiation-associated protein 1 (GDAP1) is a mitochondrial fission factor and mutations in GDAP1 cause Charcot–Marie–Tooth disease. We found that Gdap1 knockout mice (\(Gdap1^{−/−}\)), mimicking genetic alterations of patients suffering from severe forms of Charcot–Marie–Tooth disease, develop an age-related, hypomyelinating peripheral neuropathy. Ablation of Gdap1 expression in Schwann cells recapitulates this phenotype. Additionally, intra-axonal mitochondria of peripheral neurons are larger in \(Gdap1^{−/−}\) mice and mitochondrial transport is impaired in cultured sensory neurons of \(Gdap1^{−/−}\) mice compared with controls. These changes in mitochondrial morphology and dynamics also influence mitochondrial biogenesis. We demonstrate that mitochondrial DNA biogenesis and content is increased in the peripheral nervous system but not in the central nervous system of \(Gdap1^{−/−}\) mice compared with control littermates. In search for a molecular mechanism we turned to the paralogue of GDAP1, GDAP1L1, which is mainly expressed in the unaffected central nervous system. GDAP1L1 responds to elevated levels of oxidized glutathione by translocating from the cytosol to mitochondria, where it inserts into the mitochondrial outer membrane. This translocation is necessary to substitute for loss of GDAP1 expression. Accordingly, more GDAP1L1 was associated with mitochondria in the spinal cord of aged \(Gdap1^{−/−}\) mice compared with controls. Our findings demonstrate that Charcot–Marie–Tooth disease caused by mutations in GDAP1 leads to mild, persistent oxidative stress in the peripheral nervous system, which can be compensated by GDAP1L1 in the unaffected central nervous system. We conclude that members of the GDAP1 family are responsive and protective against stress associated with increased levels of oxidized glutathione.
Quantitative high-confidence human mitochondrial proteome and its dynamics in cellular context
(2021)
Mitochondria are key organelles for cellular energetics, metabolism, signaling, and quality control and have been linked to various diseases. Different views exist on the composition of the human mitochondrial proteome. We classified >8,000 proteins in mitochondrial preparations of human cells and defined a mitochondrial high-confidence proteome of >1,100 proteins (MitoCoP). We identified interactors of translocases, respiratory chain, and ATP synthase assembly factors. The abundance of MitoCoP proteins covers six orders of magnitude and amounts to 7% of the cellular proteome with the chaperones HSP60-HSP10 being the most abundant mitochondrial proteins. MitoCoP dynamics spans three orders of magnitudes, with half-lives from hours to months, and suggests a rapid regulation of biosynthesis and assembly processes. 460 MitoCoP genes are linked to human diseases with a strong prevalence for the central nervous system and metabolism. MitoCoP will provide a high-confidence resource for placing dynamics, functions, and dysfunctions of mitochondria into the cellular context.
Human leishmaniasis covers a broad spectrum of clinical manifestations ranging from self-healing cutaneous leishmaniasis to severe and lethal visceral leishmaniasis caused among other species by Leishmania major or Leishmania donovani, respectively. Some drug candidates are in clinical trials to substitute current therapies, which are facing emerging drug-resistance accompanied with serious side effects. Here, two cinnamic acid bornyl ester derivatives (1 and 2) were assessed for their antileishmanial activity. Good selectivity and antileishmanial activity of bornyl 3-phenylpropanoate (2) in vitro prompted the antileishmanial assessment in vivo. For this purpose, BALB/c mice were infected with Leishmania major promastigotes and treated with three doses of 50 mg/kg/day of compound 2. The treatment prevented the characteristic swelling at the site of infection and correlated with reduced parasite burden. Transmitted light microscopy and transmission electron microscopy of Leishmania major promastigotes revealed that compounds 1 and 2 induce mitochondrial swelling. Subsequent studies on Leishmania major promastigotes showed the loss of mitochondrial transmembrane potential (ΔΨm) as a putative mode of action. As the cinnamic acid bornyl ester derivatives 1 and 2 had exhibited antileishmanial activity in vitro, and compound 2 in Leishmania major-infected BALB/c mice in vivo, they can be regarded as possible lead structures for the development of new antileishmanial therapeutic approaches.
Aims
Autophagy protects against the development of cardiac hypertrophy and failure. While aberrant Ca2+ handling promotes myocardial remodelling and contributes to contractile dysfunction, the role of autophagy in maintaining Ca2+ homeostasis remains elusive. Here, we examined whether Atg5 deficiency-mediated autophagy promotes early changes in subcellular Ca2+ handling in ventricular cardiomyocytes, and whether those alterations associate with compromised cardiac reserve capacity, which commonly precedes the onset of heart failure.
Methods and results
RT–qPCR and immunoblotting demonstrated reduced Atg5 gene and protein expression and decreased abundancy of autophagy markers in hypertrophied and failing human hearts. The function of ATG5 was examined using cardiomyocyte-specific Atg5-knockout mice (Atg5−/−). Before manifesting cardiac dysfunction, Atg5−/− mice showed compromised cardiac reserve in response to β-adrenergic stimulation. Consequently, effort intolerance and maximal oxygen consumption were reduced during treadmill-based exercise tolerance testing. Mechanistically, cellular imaging revealed that Atg5 deprivation did not alter spatial and functional organization of intracellular Ca2+ stores or affect Ca2+ cycling in response to slow pacing or upon acute isoprenaline administration. However, high-frequency stimulation exposed stunted amplitude of Ca2+ transients, augmented nucleoplasmic Ca2+ load, and increased CaMKII activity, especially in the nuclear region of hypertrophied Atg5−/− cardiomyocytes. These changes in Ca2+ cycling were recapitulated in hypertrophied human cardiomyocytes. Finally, ultrastructural analysis revealed accumulation of mitochondria with reduced volume and size distribution, meanwhile functional measurements showed impaired redox balance in Atg5−/− cardiomyocytes, implying energetic unsustainability due to overcompensation of single mitochondria, particularly under increased workload.
Conclusion
Loss of cardiac Atg5-dependent autophagy reduces mitochondrial abundance and causes subtle alterations in subcellular Ca2+ cycling upon increased workload in mice. Autophagy-related impairment of Ca2+ handling is progressively worsened by β-adrenergic signalling in ventricular cardiomyocytes, thereby leading to energetic exhaustion and compromised cardiac reserve.
Using Expansion Microscopy to Visualize and Characterize the Morphology of Mitochondrial Cristae
(2020)
Mitochondria are double membrane bound organelles indispensable for biological processes such as apoptosis, cell signaling, and the production of many important metabolites, which includes ATP that is generated during the process known as oxidative phosphorylation (OXPHOS). The inner membrane contains folds called cristae, which increase the membrane surface and thus the amount of membrane-bound proteins necessary for the OXPHOS. These folds have been of great interest not only because of their importance for energy conversion, but also because changes in morphology have been linked to a broad range of diseases from cancer, diabetes, neurodegenerative diseases, to aging and infection. With a distance between opposing cristae membranes often below 100 nm, conventional fluorescence imaging cannot provide a resolution sufficient for resolving these structures. For this reason, various highly specialized super-resolution methods including dSTORM, PALM, STED, and SIM have been applied for cristae visualization. Expansion Microscopy (ExM) offers the possibility to perform super-resolution microscopy on conventional confocal microscopes by embedding the sample into a swellable hydrogel that is isotropically expanded by a factor of 4–4.5, improving the resolution to 60–70 nm on conventional confocal microscopes, which can be further increased to ∼ 30 nm laterally using SIM. Here, we demonstrate that the expression of the mitochondrial creatine kinase MtCK linked to marker protein GFP (MtCK-GFP), which localizes to the space between the outer and the inner mitochondrial membrane, can be used as a cristae marker. Applying ExM on mitochondria labeled with this construct enables visualization of morphological changes of cristae and localization studies of mitochondrial proteins relative to cristae without the need for specialized setups. For the first time we present the combination of specific mitochondrial intermembrane space labeling and ExM as a tool for studying internal structure of mitochondria.
In rho0-Zellen, die über keine mitochondriale DNA (mtDNA) mehr verfügen, entstehen während der Kultivierung Megamitochondrien durch endogene Milchsäure-Azidifizierung des Kulturmediums. Diese Riesenorganellen bilden sich dabei durch mitochondriale Fusionsereignisse und/oder eine Hemmung der Fission. In Zellen mit mitochondrialem Genom ist es ebenso möglich Megamitochondrien durch artifizielles Ansäuern des Kulturmediums zu induzieren. Diese Erkenntnisse wurden im Rahmen dieser Arbeit als Werkzeug verwendet, um Einblicke in mitochondriale Fusions- und Fissionsereignisse zu erlangen. Zunächst wurde die Fusion mitochondrialer Matrixkompartimente mithilfe der photoaktivierbaren Variante des grünen fluoreszierenden Proteins (PA-GFP) untersucht. Hiermit konnte gezeigt werden, dass das Vermischen der Matrixkompartimente nach der Fusion ein sehr schneller Prozess ist. Die Analyse der Bildung und Rückbildung der Megamitochondrien erfolgte sowohl konfokal- als auch elektronenmikroskopisch, wobei sich zeigte, dass die Matrix der Riesenorganellen kaum mehr Cristae beinhaltet. Die Rückbildung der Megamitochondrien zum normalen Netzwerk ist ein sehr schneller Prozess, bei dem schon nach 15 min keine vergrößerten Organellen mehr sichtbar sind. Dies indiziert, dass der Rückbildungsprozess wahrscheinlich durch Veränderungen von verfügbaren Proteinen durchgeführt wird, ohne die Induzierung von Proteinneusynthese. Untersuchungen auf ultrastruktureller Ebene zeigten, dass es während der Rückbildung zur Formation von drei unterschiedlichen Mitochondrientypen kam, die sich in ihrer Morphologie stark unterschieden. Weiterhin wurden vergleichende Studien zur Bildung der Megamitochondrien durchgeführt, bei denen der Einfluss von Atmungsketten-Inhibitoren auf die Bildung von Milchsäure-induzierten Riesenorganellen untersucht wurde. Die Resultate deuten für die Megamitochondrieninduktion auf eine Abhängigkeit auf ein intaktes Membranpotential hin. Immunzytochemisch wurde die endogene Lokalisation der mitochondrialen Fusions- und Fissionsproteine Mitofusin 2, hFis1 und Drp1/DNM1L am Modellsystem der Megamitochondrieninduktion aufgeklärt. Es zeigte sich, dass diese Proteine punktförmig an der äußeren Membran der Riesenorganellen lokalisieren Um das Modellsystem an lebenden Zellen zu nutzen, wurden Vektoren konstruiert, die fluoreszenzmarkierte Proteine der mitochondrialen Fusions- und Fissionsmaschinerie exprimierten. Hiermit konnte einerseits die Lokalisation von Mitofusin 1, Mitofusin 2, hFis1 und Drp1/DNM1L in lebenden Zellen nach Induktion der Megamitochondrien analysiert werden und andererseits der Einfluss der Überexpression dieser Proteine auf die Bildung der Riesenorganellen dokumentiert werden. Die Ergebnisse machten deutlich, dass nur die Überepxression von hFis1 die Bildung der Megamitochondrien verhinderte. Ein weiterer Schwerpunkt der vorliegenden Arbeit lag in der Visualisierung und Dynamik mitochondrialer Nucleoids in lebenden Zellen. Nucleoids sind Protein-DNA-Komplexe, in denen mitochondriale Genome organisiert sind. Mit dem Farbstoff PicoGreen gelang es mtDNA in lebenden Zellen zu färben und Dynamikstudien der punktförmigen Strukturen mikroskopisch festzuhalten. Während sich mtDNA im mitochondrialen Netzwerk nur marginal aufgrund stattfindender Fusions- und Fissionsereignisse bewegte kam es in den Milchsäure-induzierten Megamitochondrien zu einer extensiven und extrem schnellen Bewegung von mitochondrialer DNA. In anschließenden Versuchen wurde der mitochondriale Transkriptions- und Verpackungsfaktor TFAM als fluoreszentes Fusionsprotein in Zellen transfiziert und Kolokalisationsstudien zeigten, dass das Fusionsprotein mit mtDNA kolokalisiert. In den Riesenorganellen präsentierten punktförmige TFAM-gefärbte Nucleoids ein sehr dynamisches Verhalten mit schneller Bewegung. In rho0-Zellen ohne mitochondriale DNA war die TFAM-Fluoreszenz hingegen gleichmäßig verteilt. Ein weiterer Nucleiodbestandteil ist das mitochondriale DNA-Einzelstrangbindeprotein SSBP1, welches in Megamitochondrien ebenso ein sehr dynamisches Verhalten aufwies. Eine mitochondrial-zielgesteuerte und EGFP-markierte Restriktionsendonuklease wies ebenfalls das typische, punktförmige Nucleoidmuster im mitochondrialen Netzwerk auf, was auf eine Interaktion mit der mtDNA schließen lässt. In rho0-Zellen ohne mtDNA kam es jedoch zur gleichmäßigen Verteilung des Konstruktes in den Mitochondrien. Zusammenfassend wurden in dieser Arbeit sowohl Einblicke in die Biologie der Megamitochondrien gewonnen, als auch Erkenntnisse über die Dynamik mitochondrialer Protein-DNA-Komplexe, wobei der Schwerpunkt hierbei auf einer Analyse mit Hilfe optischer Methoden lag.
Viele Funktionen der Mitochondrien basieren auf Prozessen, an denen sowohl mitochondriale wie auch kernkodierte Genprodukte beteiligt sind. Durch zahlreiche Interaktionen ist der Einfluss dieser Einzelkomponenten auf das zelluläre System oftmals nur schwierig erkennbar. Mit Hilfe von rho0 -Zellen, deren Mitochondrien über kein eigenes Genom mehr verfügen, kann die mitochondriale Genkomponente ausgeschlossen werden. Im Rahmen dieser Arbeit wurden zunächst die metabolischen, proliferativen und morphologischen Eigenschaften einer rho0-Zelllinie 143B.TK-K7 untersucht, welche durch die Expression einer mitochondrial zielgesteuerten Restriktionsendonuklease hergestellt wurde. Während der Kultivierung bilden sich im Zytoplasma der 143B.TK-K7-Zellen mit fortlaufender Kultivierungszeit und zunehmenden Azidifizierung des Mediums Mega-Mitochondrien. Diese entstehen sowohl durch zahlreiche Fusionsereignisse als auch einem Schwellen durch vermehrten Wassereinfluss in die Mitochondrienmatrix. Alle Mitochondrien liegen dann als große kugelförmige Strukturen in der Zelle vor und nehmen somit die geringste Oberfläche zu einem vorhandenen Volumen ein. Die Entstehung der Mega-Mitochondrien ist dabei abhängig von einer hohen Protonenkonzentration zusätzlich zu einer ausreichend großen Menge an Laktat im Medium (Milchsäure). Zudem zeigt sich, dass auch in Zellen, welche noch ein mitochondriales Genom besitzen, durch diese Bedingungen die Bildung von Mega-Mitochondrien induziert werden kann. Bei der Entstehung der Mega-Mitochondrien handelt es sich zunächst nicht um apoptotische Vorgänge, da durch den Austausch des aziden Mediums eine äußerst schnelle Rückbildung in ein, den rho0-Zellen ähnliches Mitochondriennetzwerk erfolgt. Metabolische Untersuchungen zeigen, dass für die Rückbildung der Mega-Mitochondrien zu einem Netzwerk ausschließlich die im Medium vorhandene Protonenkonzentration ausreichend gering sein muss. Durch immunzytochemische Untersuchungen wurde deutlich, dass sowohl das mitochondriale Fusionsprotein MFN2 wie auch das Fissionsprotein DNM1L während der Entstehung und auch Rückbildung der Mega-Mitochondrien in punktförmigen Bereichen an der äußeren Mitochondrienmembran lokalisieren. Um zu überprüfen, ob die Bildung der Mega-Mitochondrien durch einer Überexpression von Proteinen der Fissionsmaschinerie verhindert wird, wurden PAGFP- bzw. EGFP-Fusionsproteine mit hFis1 und DNM1L hergestellt und in die 143B.TK-K7-Zellen transfiziert. Dabei führt eine verstärkte Expression von hFis1 zu aggregierten Mitochondrien, welche zwar anschwellen, nach einem Mediumwechsel jedoch trotzdem bestehen bleiben. Eine Überexpression von DNM1L hat keinen Einfluss auf die Entstehung und Rückbildung der Mega-Mitochondrien. Durch Inhibierung des Tubulin- bzw. Aktin-Zytoskeletts, konnte gezeigt werden, dass eine Zerstörung des Tubulin-Zytoskeletts auf die Entstehung und Rückbildung der Mega-Mitochondrien keine Auswirkungen hat. Die Untersuchungen zu dem Einfluss des Aktin-Zytoskeletts zeigen, dass die Mega-Mitochondrien ringförmig von dem Aktin-Zytoskelett umgeben sind. Mit Hilfe von Fluoreszenzprotein-Markern für die äußere und innere Mitochondrienmembran wurden die Mega-Mitochondrien als Modellsystem für mitochondriale Fusions- und Fissionsstudien verwendet. Somit konnte in der vorliegenden Arbeit mitochondriale Fusion und Fission zum ersten Mal an lebenden Zellen direkt beobachtet werden und führte nachfolgend zu der Einteilung von Fusionsvorgängen der Mitochondrien in einen Modus 1, bei dem eine zeitlich gekoppelte vollständige Fusion von sowohl äußerer wie auch innerer Membran geschieht und einen Modus 2, bei dem die Fusion der äußeren Membranen ohne die Fusion der inneren Membranen erfolgt. In ähnlicher Weise kann die Fission von Mitochondrien unterteilt werden. In einem als Modus 1 bezeichneten Mechanismus beginnt die Rückbildung der Mega-Mitochondrien zunächst mit einer Tubulierung der Mitochondrien hin zu langen Mitochondrienschläuchen, die einen nur geringen Durchmesser besitzen. Erst dann treten vermehrt zeitlich sehr schnell ablaufende Fissionsvorgänge auf. Zusätzlich wurde ein Modus 2-Mechanismus der Fission beobachtet, welcher aus einer unvollständigen Fusion resultiert, bei dem die inneren Membranen noch nicht miteinander verschmolzen sind. Auf elektronenmikroskopischer Ebene finden während der Mega-Mitochondrien-Bildung drastische Veränderung von zwiebelringartigen Cristae hin zu einer Abnahme von inneren Membranstrukturen und der elektronendichte im Matrixraum statt. Somit ist im Rahmen dieser Arbeit zum ersten Mal eine optische Beobachtung sowohl dieser Bewegungen wie auch von Fusions- und Fissionsprozessen und deren zeitlich Auflösung in vivo mit Hilfe der Mega-Mitochondrien gelungen.
Highlights
• Loss of DNAJC19's DnaJ domain disrupts cardiac mitochondrial structure, leading to abnormal cristae formation in iPSC-CMs.
• Impaired mitochondrial structures lead to an increased mitochondrial respiration, ROS and an elevated membrane potential.
• Mutant iPSC-CMs show sarcomere dysfunction and a trend to more arrhythmias, resembling DCMA-associated cardiomyopathy.
Background
Dilated cardiomyopathy with ataxia (DCMA) is an autosomal recessive disorder arising from truncating mutations in DNAJC19, which encodes an inner mitochondrial membrane protein. Clinical features include an early onset, often life-threatening, cardiomyopathy associated with other metabolic features. Here, we aim to understand the metabolic and pathophysiological mechanisms of mutant DNAJC19 for the development of cardiomyopathy.
Methods
We generated induced pluripotent stem cell-derived cardiomyocytes (iPSC-CMs) of two affected siblings with DCMA and a gene-edited truncation variant (tv) of DNAJC19 which all lack the conserved DnaJ interaction domain. The mutant iPSC-CMs and their respective control cells were subjected to various analyses, including assessments of morphology, metabolic function, and physiological consequences such as Ca\(^{2+}\) kinetics, contractility, and arrhythmic potential. Validation of respiration analysis was done in a gene-edited HeLa cell line (DNAJC19tv\(_{HeLa}\)).
Results
Structural analyses revealed mitochondrial fragmentation and abnormal cristae formation associated with an overall reduced mitochondrial protein expression in mutant iPSC-CMs. Morphological alterations were associated with higher oxygen consumption rates (OCRs) in all three mutant iPSC-CMs, indicating higher electron transport chain activity to meet cellular ATP demands. Additionally, increased extracellular acidification rates suggested an increase in overall metabolic flux, while radioactive tracer uptake studies revealed decreased fatty acid uptake and utilization of glucose. Mutant iPSC-CMs also showed increased reactive oxygen species (ROS) and an elevated mitochondrial membrane potential. Increased mitochondrial respiration with pyruvate and malate as substrates was observed in mutant DNAJC19tv HeLa cells in addition to an upregulation of respiratory chain complexes, while cellular ATP-levels remain the same. Moreover, mitochondrial alterations were associated with increased beating frequencies, elevated diastolic Ca\(^{2+}\) concentrations, reduced sarcomere shortening and an increased beat-to-beat rate variability in mutant cell lines in response to β-adrenergic stimulation.
Conclusions
Loss of the DnaJ domain disturbs cardiac mitochondrial structure with abnormal cristae formation and leads to mitochondrial dysfunction, suggesting that DNAJC19 plays an essential role in mitochondrial morphogenesis and biogenesis. Moreover, increased mitochondrial respiration, altered substrate utilization, increased ROS production and abnormal Ca\(^{2+}\) kinetics provide insights into the pathogenesis of DCMA-related cardiomyopathy.