The Structure of Bovine Mitochondrial ATP Synthase by Single Particle Electron Cryomicroscopy

Baker, Lindsay

20 August 2012

Single particle electron cryomicroscopy (cryo-EM) is a method of structure determination that uses many randomly oriented images of the specimen to construct a three-dimensional density map. In this thesis, single particle cryo-EM has been used to determine the structure of intact adenosine triphosphate (ATP) synthase from bovine heart mitochondria, an approximately 550 kDa membrane protein complex. In respiring organisms, ATP synthase is responsible for synthesizing the majority of ATP, a molecule that serves as an energy source for many cellular reactions. In order to understand the mechanism of ATP synthase, knowledge of the arrangement of subunits in the intact complex is necessary. To obtain maps of intact ATP synthase showing internal density distributions by single particle cryo-EM, methodological improvements to image acquisition, map refinement, and data selection were developed. Further, a novel segmentation algorithm was developed to aid in interpretation of maps. The use of these tools allowed for construction and interpretation of two maps of ATP synthase, solubilized in different membrane mimetics, in which the arrangement of subunits could be identified. These maps revealed interactions within the complex important for its function. In addition, evidence was obtained for curvature of membrane mimetics around ATP synthase, suggesting a role for the complex in maintenance of mitochondrial membrane morphology.

electron cryomicroscopy

ATP synthase

mitochondria

membrane protein

radiation damage

map segmentation

single particle EM

map refinement

tilt pairs

0786

Recombinant Expression, Purification, and Reconstitution of the Chloroplast ATP Synthase c-subunit Ring

January 2011

abstract: ATP synthase is a large multimeric protein complex responsible for generating the energy molecule adenosine triphosphate (ATP) in most organisms. The catalysis involves the rotation of a ring of c-subunits, which is driven by the transmembrane electrochemical gradient. This dissertation reports how the eukaryotic c-subunit from spinach chloroplast ATP synthase has successfully been expressed in Escherichia coli and purified in mg quantities by incorporating a unique combination of methods. Expression was accomplished using a codon optimized gene for the c-subunit, and it was expressed as an attachment to the larger, more soluble, native maltose binding protein (MBP-c1). The fusion protein MBP-c1 was purified on an affinity column, and the c1 subunit was subsequently severed by protease cleavage in the presence of detergent. Final purification of the monomeric c1 subunit was accomplished using reversed phase column chromatography with ethanol as an eluent. Circular dichroism spectroscopy data showed clear evidence that the purified c-subunit is folded with the native alpha-helical secondary structure. Recent experiments appear to indicate that this monomeric recombinant c-subunit forms an oligomeric ring that is similar to its native tetradecameric form when reconstituted in liposomes. The F-type ATP synthase c-subunit stoichiometry is currently known to vary from 8 to 15 subunits among different organisms. This has a direct influence on the metabolic requirements of the corresponding organism because each c-subunit binds and transports one H+ across the membrane as the ring makes a complete rotation. The c-ring rotation drives rotation of the gamma-subunit, which in turn drives the synthesis of 3 ATP for every complete rotation. The availability of a recombinantly produced c-ring will lead to new experiments which can be designed to investigate the possible factors that determine the variable c-ring stoichiometry and structure. / Dissertation/Thesis / Ph.D. Biochemistry 2011

Biochemistry

Biophysics

Biology, Plant Physiology

ATP synthase

chloroplast

coupling ratio

recombinant expression

ring stoichiometry

subunit c III ring

FoF1-ATP synthase/ATPase in the parasitic protist, \kur{Trypanosoma brucei} / FoF1-ATP synthase/ATPase in the parasitic protist, \kur{Trypanosoma brucei}

ŠUBRTOVÁ, Karolína

January 2015

This thesis primarily focuses on the FoF1-ATP synthase/ATPase complex in the parasitic protist, Trypanosoma brucei. Instead of its normal aerobic function to synthesize ATP, it is required to hydrolyze ATP to maintain the m in the infective bloodstream stage of T. brucei and the related parasite, T. b. evansi. To better understand the composition, structure and function of this druggable target, my work focused on deciphering the function of three of the unique Euglenozoa specific subunits that comprise this complex molecular machine. Furthermore, the ADP/ATP carrier, which provides substrates for the FoF1-ATP synthase/ATPase, was functionally characterized and evaluated if it is physically associated with the complexes of the oxidative phosphorylation pathway.

Morfologia da ectomicorriza Scleroderma laeve - Eucalyptus grandis e análise da expressão do gene que codifica a subunidade seis de ATP sintase / Morphology of Scleroderma laeve-Eucalyptus grandis ectomycorrhizas and expression analysis of the six subunit of ATP synthase gene

Betancourth, Blanca Mercedes Leguízamo

19 July 2011

Made available in DSpace on 2015-03-26T13:42:23Z (GMT). No. of bitstreams: 1 texto completo.pdf: 3332103 bytes, checksum: 7f48d2c607fe012e89c268995b92737e (MD5) Previous issue date: 2011-07-19 / Scleroderma laeve is a basidiomycete fungus capable of forming ectomycorrhizas with Eucalyptus grandis. Significant increases in lateral root production were observed in E. grandis plants inoculated with S. leave during the presymbiotic phase. This was also observed during the colonization, differentiation, and functioning stages of the symbiosis. On the third day of contact of the fungus with the host, the partial elongation of epidermal cells and mantle formation were observed, and, on the fifteenth day, the beginning of Hartig net formation was evident. On the 30th day, lateral root numbers in the plants in contact with the fungus was higher than in the control plants. The elongation of the epidermal cell and the thickening of the mantle could also be observed. The emerging lateral roots colonized by the fungus did not present root hairs, were completely enveloped by the fungal mantle, and had a fully developed Hartig net between the epidermal cells. The periodical sampling of lateral roots and ectomycorrhizas at different developmental stages in the in vitro system allowed following the morphological development of ectomycorrhizas and the corresponding changes in the expression of the gene coding for ATP synthase subunit VI in S. leave. The partial sequence of the ATP synthase subunit VI gene obtained possesses 503 bp and no intron. This sequences showed an identity to the sequences of the genes that code for e ATP synthase subunit VI in Scleroderma hypogaeum, Pisolithus arhizus, and Gyroporus cyanescens, among others, confirming the close relationship among these organisms. The expression analysis of the ATP synthase subunit VI gene in S. laeve by RT-PCR, at the different developmental stages of the symbiotic association, showed that the gene is expressed in all the phases of mycorrhization. / Scleroderma laeve é um fungo Basidiomiceto capaz de formar ectomicorrizas com Eucalyptus grandis. Foi observado aumento significativo do número de raízes laterais em plântulas de E. grandis em contato com S. laeve durante a fase de préinfecção em relação às plântulas não inoculadas. A inoculação com S. laeve também aumentou o número de raízes laterais em plântulas de E. grandis durante as etapas de colonização, diferenciação e funcionamento em relação às plântulas não inoculadas. No terceiro dia de contato entre o fungo e a planta, foi observado alongamento parcial das células da epiderme e formação do manto fúngico e no 15º dia foi observada a iniciação da formação da rede de Hartig. No trigésimo dia, o número de raízes laterais nas plântulas em contato com o fungo foi quatro vezes maior do que nas plântulas controle. Ocorreu, ainda, alongamento das células da epiderme e engrossamento do manto. As raízes laterais emergentes que formavam as ectomicorrizas não apresentavam pêlos radiculares, estavam totalmente envolvidas pelo manto fúngico e possuíam a rede de Hartig completamente formada entre as células alongadas da epiderme. Utilizando o sistema in vitro foi possível acompanhar, retirando-se raízes laterais e ectomicorrizas em diferentes estádios, as mudanças morfológicas da simbiose e de expressão do gene que codifica a subunidade seis de ATP sintase em S. laeve. A seqüência parcial do gene obtida possui 503 pb, na qual não foi observada a presença de introns. Essa sequência apresentou identidade com as sequências dos genes que codificam a subunidade seis de ATP sintase em S. hypogaeum, Pisolithus arhizus, Gyroporus cyanescens, entre outros, confirmando o parentesco entre esses organismos. A análise da expressão do gene que codifica a subunidade seis de ATP sintase em S. laeve por RT-PCR, nas diferentes etapas da associação, mostrou que esse gene é expresso em todas as etapas da micorrização.

Scleroderma laeve

ATP sintase

Associação ectomicorrizica

Expressão gênica

Scleroderma laeve

ATP synthase

Ectomycorrhiza association

Gene expression

CNPQ::CIENCIAS BIOLOGICAS::GENETICA

Imaging Data on Characterization of Retinal Autofluorescent Lesions in a Mouse Model of Juvenile Neuronal Ceroid Lipofuscinosis (CLN3 Disease)

Wang, Qing Jun, Jung, Kyung Sik, Mohan, Kabhilan, Kleinman, Mark E.

01 October 2020

Juvenile neuronal ceroid lipofuscinosis (JNCL, aka. juvenile Batten disease or CLN3 disease), a lethal pediatric neurodegenerative disease without cure, often presents with vision impairment and characteristic ophthalmoscopic features including focal areas of hyper-autofluorescence. In the associated research article “Loss of CLN3, the gene mutated in juvenile neuronal ceroid lipofuscinosis, leads to metabolic impairment and autophagy induction in retinal pigment epithelium” (Zhong et al., 2020) [1], we reported ophthalmoscopic observations of focal autofluorescent lesions or puncta in the Cln3Δex7/8 mouse retina at as young as 8 month old. In this data article, we performed differential interference contrast and confocal imaging analyses in all retinal layers to localize and characterize these autofluorescent lesions, including their spectral characteristics and morphology. We further studied colocalization of these autofluorescent lesions with the JNCL marker mitochondrial ATP synthase F0 sub-complex subunit C and various established retinal cell type markers.

autofluorescent lesions

CLN3

Juvenile Neuronal Ceroid Lipofuscinosis

retinopathy

vision loss

Protein-Protein-Wechselwirkungen bei der AP-3-Vesikelbildung und –fusion und der Protonenleitung durch die ATP-Synthase

Langemeyer, Lars

09 July 2010

Zu den Eigenschaften eukaryotischer Zellen gehört ihre Kompartimentierung, welche durch die Abtrennung verschiedener Reaktionsräume durch Lipiddoppelschichten erreicht wird. Verschiedene Vesikel-Transportwege verbinden diese Kompartimente miteinander, einer dieser Wege in der Hefe Saccharomyces cerevisiae ist der sogenannte ALP-Weg. Dieser gehört zu den biosynthetischen Wegen, über die neue Proteine an ihren Bestimmungsort gebracht werden, in diesem Falle die Vakuole. Ausgehend vom Golgi-Apparat werden die Vesikel dieses Weges mit Hilfe des Adaptorproteinkomplexes-3 (AP-3) gebildet. Ein weiteres Protein, das eine spezifische Funktion in diesem Weg übernimmt, ist Vps41. Ein aktuelles Modell beschreibt seine Funktion in der Aufnahme der Vesikel an der Vakuole. Es konnte gezeigt werden, das Vps41 mit der sogenannten ear-Domäne von Apl5, einer Untereinheit des AP-3- Komplexes, interagiert. In dieser Arbeit konnte ich nachweisen, dass die Interaktionsstelle im Vps41 innerhalb einer konservierten PEST-Domäne liegt. Eine Deletion dieser Domäne beeinflußte die Funktion des Proteins im ALP-Weg jedoch nicht die in der homotypischen Vakuolenfusion und im CPY-Weg. Eine weitere Eingrenzung des deletierten Bereiches zeigte, dass die PEST-Domäne eine Sequenz enthält, die einem Di-Leucin- Sortierungssignal ähnlich ist. Dieses konnte ich als minimal notwendigen Bereich für die Wechselwirkung mit der Apl5-ear-Domäne bestimmen. Meine Daten zeigen, dass dieser Bereich des Proteins notwendig ist für das Docking der AP-3-Vesikel an der Vakuole. Weiterhin konnte ich eine kompetitive Bindung von Liposomen und Apl5 an die N-terminale Hälfte von Vps41 zeigen. Zusammengefasst und mit aktuellen Veröffentlichungen in Zusammhang gebracht, ergänzen meine Daten das Modell der Funktion von Vps41 in der Vesikelaufnahme an der Vakuole: Vps41 wird durch die Rab-GTPase Ypt7, als deren Effektorprotein, an späte Endosomen gebunden. An dieser stark gekrümmten Membran taucht ein kürzlich identifiziertes ALPS (amphipathic lipid packing sensor)-Motiv im Vps41 in die Membran des Organells ein und zieht so den N-terminalen Bereich mit der Bindestelle für die AP-3-Vesikel an die Oberfläche des Organells wodurch eine verfrühte Fusion der AP-3-Vesikel mit dem Endosom verhindert wird. Erst nach der Reifung zur Vakuole wird die PEST-Domäne für die Bindung an Apl5 verfügbar, da sich die Membrankrümmung ändert. Zusätzlich wird das ALPS-Motiv phosphoryliert, so dass dieses nicht mehr in die Membran eintauchen kann. Erst jetzt ist eine Interaktion zwischen Apl5 und Vps41 und damit eine Fusion der AP-3-Vesikel mit der Vakuole möglich. Der zweite Teil dieser Arbeit beschäftigt sich mit der Protonentranslokation durch den Fo-Teil der ATP-Synthase aus Escherichia coli. Durch Mutagenese wurden ATP-Synthasen hergestellt, in denen die beiden für den Protonentransport essentiellen Aminosäurereste D61 in der Untereinheit c und R210 in der Untereinheit a in der α-Helix in der sie liegen, entweder einzeln oder beide zusammen, um je eine Helixwindung nach oben oder unten verschoben wurden. Dies führt zu einer Verlängerung bzw. Verkürzung der Protonenzu- und austrittskanäle. Durch die Untersuchung der Funktionalität dieser ATPasen auf sowohl aktives und passives Protonenpumpen, als auch ATP-Synthese konnte ich zeigen, daß die Position der beiden essentiellen Aminosäurereste cD61 und aR210 zueinander nicht entscheidend ist. Werden beide Reste in die gleiche Richtung verschoben, so daß ihre Position zueinander gleich bleibt, kommt es unabhängig von der Richtung immer zu einem kompletten Funktionsverlust. Weiterhin läßt sich aus meinen Daten folgern, daß die Position des Restes aR210 in der Mitte der Membran wichtig ist. Beim Verschieben des Restes auf die Position 206 (a-up) geht die gesamte Funktion des Fo-Teiles verloren, während das Verschieben auf die Position 214 (a-down) zu einem passiven Ausströmen der Protonen durch den Fo-Teil führt. Die Position des Restes cD61 in der Membran ist flexibler. Obwohl die Repositionierung des Aspartats auf die Position 57 (c-up) jegliche Funktionalität des Fo-Teiles beeinträchtigt, ermöglicht ein Verschieben auf die Position 65 (c-down) aktives und passives Protonenpumpen, sowie die Synthese von ATP.

FoF1-ATPase

ATP-Synthase

AP-3

ALP-Weg

Vps41

Fo-Teil

42.15 - Zellbiologie

42.12 - Biophysik

ddc:570

ddc:500

Zastoupení komponent ATP synthasomu v různých tkáních potkana a u pacientů s defektem ATP synthasy / The content of components of ATP synthasome in different rat tissues and in patients with defects in ATP synthase

Mikulová, Tereza

January 2012

The complexes of oxidative phosphorylation (OXPHOS) are situated in the inner mitochondrial membrane in higher structural and functional complexes, so-called supercomplexes, which facilitates substrate channeling. ATP synthase is also able to organize in higher structures. In mammalian mitochondria, ATP synthase is usually present in a dimeric form. There is evidence of its trimerization and even tetramerization. Furthermore, it seems that ATP synthase catalyzing the phosphorylation of ADP to ATP, adenine nucleotide translocator (ANT) ensuring the exchange of ADP for newly synthesized ATP across the inner mitochondrial membrane and phosphate carrier (PiC) allowing the import of inorganic phosphate (Pi) into the matrix of mitochondria are assembled in a supercomplex called ATP synthasome. This association among the components of phosphorylative apparatus seems to increase the efficiency of processes leading to the ATP synthesis. First, we studied amounts of the components of phosphorylative apparatus in connection with various ATP synthase contents among mitochondria isolated from nine rat tissues. Mitochondrial proteins were separated by denaturing electrophoresis (SDS-PAGE) and their content was analyzed using specific antibodies. In agreement with our expectations, the highest content of...

Hledání potenciálního vazebného partnera glutamátkarboxypeptidasy II pomocí hmotnostní spektrometrie / Mass Spectrometry-Based Identification of a Potential Binding Partner of Glutamate Carboxypetidase II

Tužil, Jan

January 2013

English Abstract The incoming paradigm of the network (or systems) biology calls for a new high throughput tool for a wide scale study of protein-protein interactions. Mass spectrometry-based proteomics have experienced a great progress in recent years and have become an indispensable technology of elementary as well as clinical research. Glutamate carboxypeptidase II (GCPII; EC 3.5.17.21) is a transmembrane protein with two known enzymatic activities. Its expression is highly upregulated in some solid tumors and also in tumor-associated neovasculature in general. Nevertheless, none of the two enzymatic activities were shown to be physiologically relevant to these cells. Some facts point at a possible receptor function of GCPII, however, no specific binding partner has been found yet. In the search for potential binding partners and/or ligands of GCPII, a series of methods have been employed, including pull-down experiment, immunoprecipitation and mass spectrometry. Sample preparation and mass spectrometry data processing methodology was specifically developed in order to identify potential binding partners. As one of the outcome of that methodology, the interaction of β-subunit of F1 ATP synthase was selected for further detailed analysis as a putative ligand of GCPII.

Mutations in atpG affect postranscriptional expression of pckA in <i>Escherichia coli</i>

Permala-Booth, Jasnehta

05 May 2008

Prokaryotic cells such as Escherichia coli use glucose as their preferred carbon source. In the absence of glucose, these cells resort to other sources to generate glucose and this process of de novo synthesis of glucose is termed gluconeogenesis. Phosphoenolpyruvate carboxykinase (Pck) is one of the three enzymes important in regulating gluconeogenesis. It converts oxaloacetic acid (OAA) from the Krebs cycle to phosphoenolpyruvate (PEP), a glycolytic intermediate. The Pck structural gene (pckA) is regulated by catabolite repression. There is a 100-fold induction of pckA-lacZ fusions at the onset of stationary phase concurrent with induction of glycogen synthesis. Mutants affecting the expression of pckA were analysed to shed some light on the mechanism of its genetic regulation.<p>Spontaneous mutants isolated with Pck- (lack of PEP carboxykinase activity) and Suc- (inability to utilise succinate as carbon source) phenotypes were previously characterised as atpG mutants defective in the ã subunit of ATP synthase.<p>In this work we find by reverse transcriptase and real time quantitative PCR that levels of pckA mRNA are normal in the atpG mutants and that the defects in expression of pckA are therefore likely at the level of translation, protein assembly and/or protein degradation. As expected, ATP synthase activity and proton pumping in inside-out membrane vesicles were defective in these atpG mutants. It is likely that one of these defects is affecting regulation or expression of the pckA gene. It was observed that atpG mutants were defective in calcium-dependent transformation although they could be made competent for electroporation. The atpG mutants were also defective for growth of P1 bacteriophage although they could serve as recipients for P1-dependent generalised transduction. These latter phenotypes are also likely due to defects in energy metabolism.

fluorescence quenching

real time reverse transcriptase PCR

gene regulation

PEP carboxykinase

atpG mutants

ATP synthase

gluconeogenesis

Escherichia coli

genetics

acridine orange

Mutations in atpG affect postranscriptional expression of pckA in <i>Escherichia coli</i>

Permala-Booth, Jasnehta

05 May 2008

Prokaryotic cells such as Escherichia coli use glucose as their preferred carbon source. In the absence of glucose, these cells resort to other sources to generate glucose and this process of de novo synthesis of glucose is termed gluconeogenesis. Phosphoenolpyruvate carboxykinase (Pck) is one of the three enzymes important in regulating gluconeogenesis. It converts oxaloacetic acid (OAA) from the Krebs cycle to phosphoenolpyruvate (PEP), a glycolytic intermediate. The Pck structural gene (pckA) is regulated by catabolite repression. There is a 100-fold induction of pckA-lacZ fusions at the onset of stationary phase concurrent with induction of glycogen synthesis. Mutants affecting the expression of pckA were analysed to shed some light on the mechanism of its genetic regulation.<p>Spontaneous mutants isolated with Pck- (lack of PEP carboxykinase activity) and Suc- (inability to utilise succinate as carbon source) phenotypes were previously characterised as atpG mutants defective in the ã subunit of ATP synthase.<p>In this work we find by reverse transcriptase and real time quantitative PCR that levels of pckA mRNA are normal in the atpG mutants and that the defects in expression of pckA are therefore likely at the level of translation, protein assembly and/or protein degradation. As expected, ATP synthase activity and proton pumping in inside-out membrane vesicles were defective in these atpG mutants. It is likely that one of these defects is affecting regulation or expression of the pckA gene. It was observed that atpG mutants were defective in calcium-dependent transformation although they could be made competent for electroporation. The atpG mutants were also defective for growth of P1 bacteriophage although they could serve as recipients for P1-dependent generalised transduction. These latter phenotypes are also likely due to defects in energy metabolism.

fluorescence quenching

real time reverse transcriptase PCR

gene regulation

PEP carboxykinase

atpG mutants

ATP synthase

gluconeogenesis

Escherichia coli

genetics

acridine orange