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Mitochondrial copper homeostasis in mammalian cells / Mitochondrialer Kupfermetabolismus in SäugerzellenOswald, Corina 05 October 2010 (has links) (PDF)
Assembly of cytochrome c oxidase (COX), the terminal enzyme of the mitochondrial respiratory chain, requires a concerted activity of a number of chaperones and factors for the correct insertion of subunits, accessory proteins, cofactors and prosthetic groups. Most of the fundamental biological knowledge concerning mitochondrial copper homeostasis and insertion of copper into COX derives from investigations in the yeast Saccharomyces cerevisiae. In this organism, Cox17 was the first identified factor involved in this pathway. It is a low molecular weight protein containing highly conserved twin Cx9C motifs and is localized in the cytoplasm as well as in the mitochondrial intermembrane space. It was shown that copper-binding is essential for its function.
So far, the role of Cox17 in the mammalian mitochondrial copper metabolism has not been well elucidated. Homozygous disruption of the mouse COX17 gene leads to COX deficiency followed by embryonic death, which implies an indispensable role for Cox17 in cell survival.
In this thesis, the role of COX17 in the biogenesis of the respiratory chain in HeLa cells was explored by use of siRNA. The knockdown of COX17 results in a reduced steady-state concentration of the copper-bearing subunits of COX and affects growth of HeLa cells accompagnied by an accumulation of ROS and apoptotic cells. Furthermore, in accordance with its predicted function as a copper chaperone and its role in formation of the binuclear copper center of COX, COX17 siRNA knockdown affects COX-activity and -assembly. It is now well accepted that the multienzyme complexes of the respiratory chain are organized in vivo as supramolecular functional structures, so called supercomplexes. While the abundance of COX dimers seems to be unaffected, blue native gel electrophoresis reveals the disappearance of COX-containing supercomplexes as an early response. Accumulation of a novel ~150 kDa complex containing Cox1, but not Cox2 could be observed. This observation may indicate that the absence of Cox17 interferes with copper delivery to Cox2, but not to Cox1. Data presented here suggest that supercomplex formation is not simply due to assembly of completely assembled complexes. Instead an interdependent assembly scenario for the formation of supercomplexes is proposed that requires the coordinated synthesis and association of individual complexes.
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Mitochondrial copper homeostasis in mammalian cellsOswald, Corina 13 August 2010 (has links)
Assembly of cytochrome c oxidase (COX), the terminal enzyme of the mitochondrial respiratory chain, requires a concerted activity of a number of chaperones and factors for the correct insertion of subunits, accessory proteins, cofactors and prosthetic groups. Most of the fundamental biological knowledge concerning mitochondrial copper homeostasis and insertion of copper into COX derives from investigations in the yeast Saccharomyces cerevisiae. In this organism, Cox17 was the first identified factor involved in this pathway. It is a low molecular weight protein containing highly conserved twin Cx9C motifs and is localized in the cytoplasm as well as in the mitochondrial intermembrane space. It was shown that copper-binding is essential for its function.
So far, the role of Cox17 in the mammalian mitochondrial copper metabolism has not been well elucidated. Homozygous disruption of the mouse COX17 gene leads to COX deficiency followed by embryonic death, which implies an indispensable role for Cox17 in cell survival.
In this thesis, the role of COX17 in the biogenesis of the respiratory chain in HeLa cells was explored by use of siRNA. The knockdown of COX17 results in a reduced steady-state concentration of the copper-bearing subunits of COX and affects growth of HeLa cells accompagnied by an accumulation of ROS and apoptotic cells. Furthermore, in accordance with its predicted function as a copper chaperone and its role in formation of the binuclear copper center of COX, COX17 siRNA knockdown affects COX-activity and -assembly. It is now well accepted that the multienzyme complexes of the respiratory chain are organized in vivo as supramolecular functional structures, so called supercomplexes. While the abundance of COX dimers seems to be unaffected, blue native gel electrophoresis reveals the disappearance of COX-containing supercomplexes as an early response. Accumulation of a novel ~150 kDa complex containing Cox1, but not Cox2 could be observed. This observation may indicate that the absence of Cox17 interferes with copper delivery to Cox2, but not to Cox1. Data presented here suggest that supercomplex formation is not simply due to assembly of completely assembled complexes. Instead an interdependent assembly scenario for the formation of supercomplexes is proposed that requires the coordinated synthesis and association of individual complexes.:List of Figures and Tables
Abbreviations
Abstract
1 Indroduction
1.1 Mitochondria and the respriratory chain
1.2 The human mitochondrial genome
1.3 Homoplasmy and heteroplasmy
1.4 Mitochondrial disorders
1.4.1 Mutations in mitochondrial DNA
1.4.2 Mutations in nuclear DNA
1.5 Cytochrome c oxidase
1.6 Cytochrome c oxidase assembly
1.7 Copper and its trafficking in the cell
1.8 Mitochondrial copper metabolism
1.9 Cox17
1.10 Aims of the thesis
2 Materials and Methods
2.1 Materials
2.1.1 Chemicals and reagents
2.1.2 Antibodies
2.1.3 Plasmid
2.1.4 Kits
2.1.5 Marker
2.1.6 Enzymes
2.1.7 Primers
2.1.8 siRNAs
2.2 Methods
2.2.1 Cell culture
2.2.1.1 Cell culture: HeLa cells
2.2.1.2 Cell culture: HeLa cells transfected with pTurboRFP-mito
2.2.1.3 Subcultivation
2.2.1.4 Determination of cell number
2.2.1.5 Cell storage and thawing
2.2.2 Transient transfection of HeLa cells
2.2.3 Transfection of HeLa cells with pTurboRFP-mito
2.2.4 Immunocytochemistry
2.2.5 RNA extraction and quantitative real-time PCR
2.2.6 Isolation of mitochondria
2.2.6.1 Isolation of mitochondria for BN-PAGE Analysis
2.2.6.2 Isolation of mitochondria for localization studies
2.2.6.3 Isolation of bovine heart mitochondria
2.2.7 Proteinase K treatment of mitochondria and mitoplasts
2.2.8 Photometric activity assay
2.2.8.1 Citrate synthase activity
2.2.8.2 Cytochrome c oxidase activity
2.2.9 Blue native polyacrylamide gel electrophoresis (BN-PAGE)
2.2.9.1 In gel activity assay
2.2.9.2 2D-BN/SDS-PAGE
2.2.10 SDS-PAGE and Western blot analysis
2.2.11 Direct stochastic optical reconstruction microscopy (dSTORM)
2.2.12 Flow cytometric phenotyping
2.2.12.1 Determination of cell cyle phase
2.2.12.2 Identification of apoptotic cells
2.2.12.3 Detection of ROS
2.2.13 Oxygen measurement
2.2.14 Cu–His supplementation
3 Results
3.1 Subcellular localization of Cox17
3.2 Transient knockdown of COX17 in HeLa cells
3.2.1 Knockdown of COX17 mRNA
3.2.2 Knockdown of Cox17 protein
3.2.3 Effect of COX17 knockdown on the steady-state levels of OXPHOS
subunits
3.2.4 Effect of COX17 knockdown on the steady-state levels of copperbearing COX subunits
3.2.5 Subdiffraction-resolution fluorescence imaging
3.3 Phenotypical characterization
3.3.1 Growth analyis
3.3.2 Cell cycle analysis
3.3.3 Apoptosis assay
3.3.4 Detection of ROS
3.3.5 Oxygen measurement
3.4 Cytochrome c oxidase activity
3.5 Characterization of mt OXPHOS complexes
3.5.1 BN-PAGE/in gel activity assays
3.5.2 Supramolecular organization of COX
3.5.3 Molecular organization of Cox17
3.5.4 Molecular organisation of copper-bearing COX subunits Cox1 and
Cox2
3.5.5 Supramolecular organization of RC complexes
3.5.6 dSTORM of supercomplexes
3.6 Copper supplementation
4 Discussion
4.1 Dual localization of human Cox17
4.2 COX17 knockdown affects steady-state levels of copper-bearing
COX subunits Cox1 and Cox2
4.3 Supramolecular organization of RC is affected as an early response
to COX17 knockdown
4.4 Cox17 is primarily engaged in copper delivery to Sco1/Sco2
4.5 Copper supplementation alone cannot rescue the COX17
phenotype
4.6 Outlook
5 Appendix
6 PhD publication record
7 References
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Control and function of two ferrochelatase isoforms in Arabidopsis thalianaFan, Tingting 18 March 2019 (has links)
Die Tetrapyrrol-Biosynthese der Pflanzen ist ein hoch konservierter Prozess, indem sich die Häm- und Chlorophyllsynthese gemeinsame Syntheseschritte von der 5-Aminolävulinsäure (ALA)- bis hin zur Protoporphyrin IX (Proto)-Bildung teilen. Zur Hämsynthese sind in Arabidopsis thaliana zwei Isoformen der Ferrochelatase (FC) vorhanden, welche die Insertion von Eisenionen in Proto katalysieren.
In dieser Arbeit wurden fc1 und fc2 Mutanten analysiert und für Komplementationsversuche mit nativen und modifizierten FC1/FC2-Sequenzen genutzt. Die in der fc1-2 Mutante gestörte Embryonalentwicklung infolge des FC1 Mangels konnte durch Expression eines pFC1::FC1 Genkonstruktes komplementiert werden. Die Expression von FC2 unter dem FC1 Promoter (pFC1::FC2) konnte die fc1-2 Mutante unter Standard-Wachstumsbedingungen vollständig komplementieren, jedoch nicht unter Salzstress.
Zusätzlich zu den Komplementationsversuchen der fc1 Mutanten wurde auch eine fc2 Null-Mutante zur Expression der beiden genomischen FC Sequenzen herangezogen, um die spezifischen Funktionen der FC2-Varianten zu untersuchen. Während die pFC1FC2 (fc2/fc2) Pflanzen unter Dauerlicht eine vollständige Komplementation zeigten, konnte unter Kurztagbedingungen nur eine partielle Komplementation beobachtet werden. Versuche geben erste wichtige Hinweise, dass auch FC2 an der Regulation der ALA-Synthese infolge ihrer Interaktion mit PORB beteiligt ist. Dies deutet darauf hin, dass der Häm- und der Chlorophyllzweig eine gemeinsame Regulation der ALA-Synthese teilen, um das Gleichgewicht der TBS zu wahren.
Neben der Funktion der FC2 in der Regulation der TBS konnte die vorliegende Arbeit ebenfalls die Rolle der FC2 in der Assemblierung der PSII-LHCII Superkomplexe offenlegen.
Basierend auf den Ergebnissen, dieser Studie können Modelle für die funktionale Verteilung der beiden FC-Isoformen in unterschiedlichen Geweben und Entwicklungsstadien, sowie die Funktionen in verschiedenen biologischen Prozessen postuliert werden. / In plants, heme and chlorophyll synthesis share the common synthetic steps from 5- aminolevulinic acid (ALA) formation to Protoporphyrin IX (Proto) production in the conserved Tetrapyrrole biosynthesis (TBS) pathway. Arabidopsis thaliana utilizes two ferrochelatses (FC) to catalyse the insertion of ferrous iron into Proto to yield heme.
In this study, the fc1 and fc2 defective mutants have been re-analysed and used for complementation tests with expression of a native or modified FC1/FC2 sequence. The pFC1FC1 (fc1/fc1) complementation plants confirmed that the defective embryo maturation in homozygous fc1-2 seeds is attributed to a lack of FC1. Expression of FC2 under the FC1 promoter contributed to a full complementation of fc1-2 under standard growth conditions, but not under salt stress.
A fc2 null mutant has been used to express the two FC genomic sequences to substantiate the specific functions of FC2. Expression of FC2 under its own promoter was able to rescue fc2-2 mutants under both SD and CL conditions. However, pFC2FC1 (fc2/fc2) plants showed a partial complementation under SD condition. Via multiple interaction assays and mutant analyses, this thesis uncovered a mechanism of FC2 action on ALA synthesis regulation via interaction of FC2 and PORB. The results indicate that both branches of heme and chlorophyll synthesis share a common regulation to balance the TBS pathway.
Apart from a role of FC2 involved in the regulation of TBS pathway, the presented study also revealed FC2 function in the assembly of the PSII-LHCII supercomplexes.
Based on all the results obtained in this study, the functional distribution models of the two FC in different tissues and development stages, as well as diverse biological processes, have been proposed. In addition, to which extent that FC1/FC2 could compensate the function of the other isoform has been discussed.
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