Inhibition of the Toxoplasma gondii replication by inhibition of the mitochondrial respiratory chain / Inhibierung der Toxoplasma-gondii-Replikation durch Hemmung der mitochondrialen Atmungskette

Naujoks, Britta

12 December 2008

No description available.

610 Medizin, Gesundheit

Medicine

HDQ

Toxoplasma gondii

Atmungskette

Angriffspunkte

HDQ

Toxoplasma gondii

respiratory chain

drug target

Medizin

Medizin

Yeast mitochondrial copper metabolism: topology and role of Cox11p

Khalimonchuk, Oleh

16 January 2006

Cytochrome c oxidase (COX) is one of two known Cu-containing enzymes in mitochondria. Delivery and insertion of copper into COX are very complex processes that require multiple steps and involve a large number of assisting factors. One of the involved components is Cox11p, a copper binding protein in the inner mitochondrial membrane that is conserved from prokaryotes to eukaryotes. Cox11p is essential for respiratory growth and implicated in the assembly of the CuB site located in subunit Cox1p of COX. In the thesis the topology of Cox11p was determined and evidence for its association with the mitochondrial translation machinery is provided. The interaction of Cox11p with mitoribosomes is mediated by its single evolutionary conserved transmembrane segment and appears to be indirect and mediated by another conserved membrane protein(s). A model is proposed in which the CuB site is co-translationally formed by a transient interaction between Cox11p and the nascent Cox1p in the mitochondrial intermembrane space. In addition the genetic and biochemical characterization of S. pombe Cox11p homologue was performed. Two versions of cox11+ gene are detected in a haploid S. pombe genome. Cells lacking either of the cox11+ copies remain respiratory competent, whereas deletion of both S. pombe cox11+ alleles appears to result in either spore lethality or in severe decrease of spores viability. Thus, both versions of SpCox11p are functional and important. In S. pombe Cox11p exists as a tandem with the mitoribosomal protein Rsm22p. This precursor protein is cleaved during mitochondrial import into two mature protein species corresponding to Rsm22p- and Cox11p-like moieties.

cytochrom c oxidase

hefe Saccharomyces cerevisiae

mitochondria

Cox11p

Saccharomyces cerevisiae

cytochrome c oxidase

mitochondria

yeast

ddc:570

rvk:WF 9100

Atmungskette

Cox11p

Cytochromoxidase

Hefeartige Pilze

Kupferstoffwechsel

Mitochondrium

Mitochondrial copper homeostasis in mammalian cells / Mitochondrialer Kupfermetabolismus in Säugerzellen

Oswald, Corina

05 October 2010

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.

Cytochrome C Oxidase

Cox17

Superkomplexe

Mitochondrien

Kupfer

Atmungskette

HeLa

cytochrome c oxidase

Cox17

supercomplexes

mitochondria

copper

respiratory chain

HeLa

ddc:570

rvk:WE 3100

Analysis of the role of Mdm38 in respiratory chain biogenesis / Die Funktion von Mdm38 in der Biogenese der Atmungskette

Vollmer, Christine

31 May 2011

No description available.

000 Allgemeines, Wissenschaft

Biology (incl. Psychology)

Mitochondrien

Atmungskette

Ribosomen

LETM1 homolog

Mitochondria

respiratory chain

ribosomes

LETM1 homologue

30

42

W

RA

Biogenesis of respiratory chain: Rcf1 and Rcf2 as a novel assembly factors / Biogenese der Atmungskette: Rcf1 und Rcf2 als neue Assemblierungsfaktoren

Vukotic, Milena

07 June 2012

No description available.

570 Biowissenschaften, Biologie

WA 000 Biologie

Biology (incl. Psychology)

Atmungskette

Assemblierungsfaktoren

Mitochondria

Atmungskettenkomplexe

Respirasome

Hypoxie

42 Biologie

Mitochondrial copper homeostasis in mammalian cells

Oswald, Corina

13 August 2010

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

info:eu-repo/classification/ddc/570

ddc:570

Modeling the respiratory chain and the oxidative phosphorylation

Heiske, Margit

16 April 2013

Die oxidative Phosphorylierung (OXPHOS) spielt eine zentrale Rolle im Energiestoffwechsel der Zelle. Sie besteht aus der Atmungskette, deren vier Enzymkomplexe einen Protonengradienten über die innere mitochondriale Membran aufbauen, und der ATP-Synthase, die diesen Gradienten zur Phosphorylierung von ADP zu ATP, der zelluläre Energieeinheit, nutzt. In der vorliegenden Arbeit wurde ein thermodynamisch konformes OXPHOS Modell erstellt, welches auf Differentialgleichungen basiert. Dazu wurden Gleichungen entwickelt, welche die Kinetiken jedes OXPHOS-Komplexes über weite Bereiche von Substrat- und Produktkonzentrationen sowie unterschiedlichster Werte des elektrochemischen Gradientens wiedergeben. Zunächst wurden für jeden Komplex der Atmungskette kinetische Messungen in Abwesenheit des Protonengradientens durchgeführt. Für deren Beschreibung erwiesen sich Gleichungen vom Typ Michaelis-Menten als adäquat; hierbei wurden verschiedene Gleichungstypen verglichen. Anschließend wurde der Einfluss des Protonengradientens auf die kinetischen Parameter so modelliert, dass physiologisch sinnvolle Raten in dessen Abhängigkeit erzielt werden konnten. Diese neuen Ratengleichungen wurden schließlich in ein OXPHOS Modell integriert, mit dem sich experimentelle Daten von Sauerstoffverbrauch, elektrischem Potential und pH-Werten sehr gut beschreiben ließen. Weiter konnten Inhibitor-Titrationskurven reproduziert werden, welche den Sauerstoffverbrauch in Abhängigkeit der relativen Hemmung eines OXPHOS-Komplexes darstellen. Dies zeigt, dass lokale Effekte auf globaler Ebene korrekt wiedergeben werden können. Das hier erarbeitete Modell ist eine solide Basis, um die Rolle der OXPHOS und generell von Mitochondrien eingehend zu untersuchen. Diese werden mit zahlreichen zellulären Vorgängen in Verbindung gebracht: unter anderem mit Diabetes, Krebs und Mitochodriopathien, sowie der Bildung von Sauerstoffradikalen, die im Zusammenhang mit Alterungsprozessen stehen. / Oxidative phosphorylation (OXPHOS) plays a central role in the cellular energy metabolism. It comprises the respiratory chain, consisting of four enzyme complexes that establish a proton gradient over the inner mitochondrial membrane, and the ATP-synthase that uses this electrochemical gradient to phosphorylate ADP to ATP, the cellular energy unit. In this work a thermodynamically consistent OXPHOS model was built based on a set of differential equations. Therefore rate equations were developed that describe the kinetics of each OXPHOS complex over a wide concentration range of substrates and products as well for various values of the electrochemical gradient. In a first step, kinetic measurements on bovine heart submitochondrial particles have been performed in the absence of the proton gradient. An appropriate data description was achieved with Michaelis-Menten like equations; here several types of equations have been compared. The next step consisted in incorporating the proton gradient into the rate equations. This was realized by distributing its influence among the kinetic parameters such that reasonable catalytic rates were obtained under physiological conditions. Finally, these new individual kinetic rate expressions for the OXPHOS complexes were integrated in a global model of oxidative phosphorylation. This new model could fit interrelated data of oxygen consumption, the transmembrane potential and the redox state of electron carriers. Furthermore, it could well reproduce flux inhibitor titration curves, which validates its global responses to local perturbations. This model is a solid basis for analyzing the role of OXPHOS and mitochondria in detail. They have been linked to various cellular processes like diabetes, cancer, mitochondrial disorders, but also to the production of reactive oxygen species, which are supposed to be involved in aging.

Systembiologie

mathematische Modellierung

Energiemetabolismus

Atmungskette

oxidative Phosphorylierung

Mitochondrium

Enzymkinetik

Protonengradient

systems biology

mitochondria

mathematical modeling

energy metabolism

respiratory chain

oxidative phosphorylation

enzyme kinetics

proton gradient

570 Biowissenschaften, Biologie

32 Biologie

WX 3304

ddc:570

Yeast mitochondrial copper metabolism: topology and role of Cox11p

Khalimonchuk, Oleh

15 February 2006

Cytochrome c oxidase (COX) is one of two known Cu-containing enzymes in mitochondria. Delivery and insertion of copper into COX are very complex processes that require multiple steps and involve a large number of assisting factors. One of the involved components is Cox11p, a copper binding protein in the inner mitochondrial membrane that is conserved from prokaryotes to eukaryotes. Cox11p is essential for respiratory growth and implicated in the assembly of the CuB site located in subunit Cox1p of COX. In the thesis the topology of Cox11p was determined and evidence for its association with the mitochondrial translation machinery is provided. The interaction of Cox11p with mitoribosomes is mediated by its single evolutionary conserved transmembrane segment and appears to be indirect and mediated by another conserved membrane protein(s). A model is proposed in which the CuB site is co-translationally formed by a transient interaction between Cox11p and the nascent Cox1p in the mitochondrial intermembrane space. In addition the genetic and biochemical characterization of S. pombe Cox11p homologue was performed. Two versions of cox11+ gene are detected in a haploid S. pombe genome. Cells lacking either of the cox11+ copies remain respiratory competent, whereas deletion of both S. pombe cox11+ alleles appears to result in either spore lethality or in severe decrease of spores viability. Thus, both versions of SpCox11p are functional and important. In S. pombe Cox11p exists as a tandem with the mitoribosomal protein Rsm22p. This precursor protein is cleaved during mitochondrial import into two mature protein species corresponding to Rsm22p- and Cox11p-like moieties.

info:eu-repo/classification/ddc/570

ddc:570