Refine
Year of publication
Document Type
- Doctoral Thesis (70)
Language
- English (70) (remove)
Has Fulltext
- yes (70)
Is part of the Bibliography
- no (70)
Keywords
Institute
- Biochemie und Chemie (59)
- Biowissenschaften (6)
- Biochemie, Chemie und Pharmazie (3)
- Pharmazie (2)
- MPI für Biophysik (1)
Plants absorb sunlight via photosynthetic pigments and convert light energy intochemical energy in the process of photosynthesis. These pigments are mainly bound to antenna protein complexes that funnel the excitation energy to the photosynthetic reaction centres. The peripheral antenna of plant photosystem II (PSII) consists of the major light-harvesting complex of PSII (LHC-II) and the minor LHCs CP29, CP26 and CP24. Light intensity can change frequently and plants need to adapt to high-light conditions in order to avoid photodamage. When more photons are absorbed than can be utilised by the photosynthetic machinery, excessive excitation energy is dissipated as heat by short-term adaptation processes collectively known as non-photochemical quenching (NPQ). A decrease in PSII antenna chlorophyll (Chl) fluorescence yield and a reduction in the average Chl fluorescence lifetime are associated with NPQ. The main component of NPQ is the so-called energy-dependent quenching (qE), and it is triggered by the rapid drop in thylakoid lumenal pH resulting from the plant’s photosynthetic activity. This process is thought to take place at the PSII antenna complexes, which therefore not only capture and transfer light energy but are also involved in balancing the energy flow. The decrease in lumenal pH acivates the enzyme violaxanthin de-epoxidase (VDE), which converts the xanthophyll violaxanthin (Vio) into zeaxanthin (Zea) in the xanthophyll cycle. In addition, the PSII subunit PsbS was discovered to be essential for qE by screening qE-deficient Arabidopsis thaliana mutants. This membrane protein is considered a member of the LHC superfamily, which also includes LHC-II and the minor LHCs. Previous studies on PsbS isolated either from native source or refolded in vitro have produced inconsistent results on its pigment binding capacity. Interestingly, a pH-dependent change in the quaternary structure of PsbS under high light conditions has been reported. This observed dimer-tomonomer transition very likely follows the protonation of lumenal glutamates upon the drop in pH and is accompanied by a change in PSII supercomplex localisation. PsbS dimers are preferentially found in association with the PSII core, whereas PsbS monomers co-localise with LHC-II.Despite the identification of !pH, Zea and PsbS as key players in qE, both the nature of the quencher(s) as well as the underlying molecular mechanism leading to excess energy dissipation still remain unknown. Several models have been put forward to explain the reversible switch in the antenna from an energy-transmitting to a quenched state. Proposals include a simple pigment exchange of Vio for Zea, and aggregation or an internal conformational change of LHC-II. Charge transfer (CT)quenching in the minor LHCs or quenching by carotenoid dark state (Car S1)-Chl interactions have also been suggested. However, none of these qE models has so far been capable of accommodating all the physiological observations and available experimental data. Most importantly, the function of PsbS remains an enigma. A recent qE model suggested that monomerisation of PsbS enables the protein to transiently bind a carotenoid and form a quenching unit with a Chl of a PSII LHC. In view of the various proposed qE mechanisms, this thesis aimed at understanding the interplay of the different qE components and the contribution of the PSII subunits LHC-II, the minor LHCs and PsbS to qE. The initial approach was to investigate the properties of the PSII subunits in the most simple in vitro model system, namely in detergent solution. For this purpose, LHC-II was isolated either from native source or refolded from recombinantly produced protein. Investigation of the minor LHCs and PsbS required heterologous expression and refolding. In addition, experiments were performed on aggregated LHC-II. Aggregates of LHC-II have been used as a popular model system for qE because they exhibit highly quenched Chl fluorescence. At the final stage of this doctoral work, a more sophisticated model system to approximate the thylakoid membrane was developed by reconstitution of the PSII subunits LHC-II and PsbS into liposomes. This system not only allowed for investigation of these membrane proteins in their native environment, but also for mimicking the xanthophyll cycle by distribution of Zea within the membrane as well as !pH by outside buffer exchange. The role of Zea in qE was first investigated with detergent solubilised antenna proteins. The requirement of this xanthophyll for qE is well-known, but the specific contribution to the molecular quenching mechansim is unclear. Previous work had shown that replacement of Vio for Zea in LHC-II was not sufficient to induce Chl fluorescence quenching in Zea-LHC-II, as suggested by the so-called molecular gearshift mechanism. However, by means of selective two-photon excitation spectroscopy, an increase in electronic interactions between Car S1 and Chls was observed for LHC-II upon lowering the pH of the detergent buffer. Electronic Car S1-Chl coupling became even stronger when Zea-LHC-II was probed. The extent of Car S1-Chl coupling correlated directly with the extent of Chl fluorescence quenching, in a similar way as observed previously in live plants under high-light conditions. However, very similar results were obtained with LHC-II aggregates. This implied that the increase in electronic interactions and fluorescence quenching was independent of Zea and low pH. Further experiments on aggregates of LHC-II Chl mutants indicated that the targeted pigments were also not essential for the observed effects. It is proposed that the same molecular mechanism causes an increase in electronic Car S1-Chl interactions and Chl fluorescence quenching in Zea-LHC-II at low pH as well as in aggregated LHC-II. Most likely, surface exposed pigments form random quenching centres in both cases. On the other hand, it was possible that Zea could act as a direct quencher of excess excitation energy in the minor LHCs. However, enrichment of refolded CP29, CP26 and CP24 with Zea did not lead to a change in the Chl excited state lifetime. Formation of a carotenoid radical cation, previously implied in CT quenching, was also not observed, although artificial generation of such a radical cation was principally possible as shown for CP29. During the course of this work, a study reporting the formation of Zea radical cations in minor LHCs was published. Therefore, Zea-enriched minor LHCs were again investigated on the experimental apparatus used in the reported study. Indeed, the presence of at least one carotenoid radical cation for each minor complex was detected. It is suggested that either the preparation method of incubating the refolded minor LHCs with Zea in contrast to refolding the complexes with only Zea and lutein causes the observed differences or that the observed spectral radical cation signatures are due to experimental artifacts. While the experiments with LHC-II and the minor LHCs gave useful insights into the putative qE mechanism, the quencher site and the mode of action of Zea could still not be unambiguously identified. Most importantly, these studies could not explain the function of the qE keyplayer PsbS. Therefore, the focus of the work was shifted to PsbS protein production, purification and characterisation. In view of inconsistent reports on the pigment binding capacity of this PSII subunit, refolding trials with and without photosynthetic pigments were conducted. The formation of a specific pigmentprotein complex typical for other LHCs was not observed and neither was the earlier reported “activation” of Zea for qE by binding to this protein. Nevertheless, PsbS refolded without pigments displayed secondary structure content in agreement with previous studies, indicating pigment-independent folding. Reconstitution of pigmentfree, refolded PsbS into liposomes confirmed that the protein is stable in the absence of pigments. Zea distributed in PsbS-containing liposomes also showed no spectral alteration that would indicate its “activation”. With the ability to reconstitute PsbS, it was then possible to proceed to modelling qE in a proteoliposome system. For this purpose, PsbS was co-reconstituted with LHC-II, which has been reported to interact with PsbS. One-photon excitation (OPE) and two-photon excitation (TPE) spectroscopy measurements were performed on LHC-II- and LHC-II/PsbS-containing liposomes. This enabled both quantification of Chl fluorescence quenching as well as determination of the extent of electronic Car S1-Chl interactions. The effect of Zea was investigated by incorporating it in the proteoliposome membrane. It was shown that Zea alone was not able to induce significant Chl fluorescence quenching when only LHC-II was present. However, when LHC-II and PsbS were co-reconstituted, pronounced Chl fluorescence quenching and an increase in electronic Car S1-Chl interactions were observed and both effects were enhanced when Zea was present. Western blot analysis indicated the presence of a LHC-II/PsbS-heterodimer in these proteoliposomes. In addition to the OPE and TPE measurements, the average Chl fluorescence lifetime was determined in detergent-free buffer at neutral pH and directly after buffer exchange to low pH. No significant changes in the average lifetime were observed for LHC-II proteoliposomes when either Zea was present or after exchange for low pH buffer. This indicated that Zea alone cannot act as a direct quencher, which concurs with the OPE measurements. Moreover, the complex was also properly reconstituted as no aggregation or significant Chl fluorescence quenching were observed. The average lifetime was not significantly affected in LHC-II/PsbS-proteoliposomes, independent of Zea or pH. However, a shortlived component in the presence of a long-lived component was not resolvable with the time resolution of the fluorescence lifetime apparatus.
Implications for qE model systems and the in vivo quenching mechanism are discussed based on the experiments in detergent solution, on LHC-II aggregates and with the proteoliposome model system.
ATP synthases are multi-subunit membrane enzymes, which utilize the energy stored in a transmembrane electrochemical ion gradient to produce adenosine-5´-triphosphate (ATP), the universal energy carrier in biological systems. Research on these important enzymes goes back more than 50 years and has produced innumerable studies. The F-type ATP synthase consists of two functionally distinct, but tightly coupled subcomplexes, the water-soluble F1 and the membrane-embedded Fo complex. In its simplest form, F1 consists of five different subunits with a stoichiometry of α 3β3γδε, and harbors three catalytic centers in the α 3β3-headpiece, while Fo consists of three different subunits in a stoichiometry of ab2cn, where n varies between 8 to 15 depending on the species. From a mechanistic standpoint, the complex can also be divided into two different units, namely a stator, α3β3δ-ab2, and a rotor, γε-cn. The enzyme utilizes the energy stored in a transmembrane electrochemical gradient of protons, or in some cases Na+, to drive ATP synthesis. In particular, the downhill translocation of these ions across the Fo complex drives rotation of the γε-cn unit, which is then transduced to the active centers, catalyzing the phosphorylation of adenosine-5`-diphosphate (ADP) with inorganic phosphate (Pi), and the release of ATP....
Respiration is one of the key processes of energy transduction used by the cell. It consists of two components: electron transfer and ATP production. The electron transfer chain converts the energy released from several biochemical redox reactions into an electrochemical proton gradient across membranes. This stored energy is used as the driving force for the production of ATP by the ATP synthase. The mitochondrial electron transfer chain contains four major protein complexes called complexes I-IV, with counting starting at the lower side of the redox potentials. It has been discussed for a long time how these protein complexes are organized in the membranes. Do they diffuse freely in the membrane? Alternatively, do they form a supercomplex built up of several neighboring complexes? The evidence supporting the free diffusion mode is that both electron transfer intermediates (cytochrome c and quinone) behave as “pool”. However, respiratory supercomplexes have been detected in membranes from bacteria, fungi, yeast, plant and animal during the last decade, and sometimes the respiratory complexes are only stable inside a supercomplex. Therefore, the idea of supercomplex formation has become more popular. The argument that the supercomplex arises from solubilization and is a detergent artifact could be rejected because: 1) supercomplexes can be isolated from many organisms in an active form; 2) supercomplexes have been proven to stabilize the individual complexes in some cases; 3) supercomplexes can be very stable after chromatographic isolation in some cases....
The four subunit (SU) aa3 cytochrome c oxidase (CcO) from Paracoccus denitrificans is one of the terminal enzymes of the respiratory chain. It uses electrons from cytochrome c to reduce molecular oxygen to water. Its binuclear active center, residing in SU I, contains hemeÊa3 and CuB, the latter being liganded by three histidine residues. Apart from its oxygen reductase activity, the protein possesses a peroxidase and a catalase activity.
To compare variants and the wild type (WT) protein in a more stringent way, a recombinant (rec.) WT CcO was constructed, carrying the gene for SUÊI on a low copy number plasmid. This rec. WT showed, as expected, no difference in oxygen reductase activity compared to the American Type Culture Collection (ATCC) WT CcO but surprisingly its catalase activity was increased by a factor of 20. The potential overproduction of SUÊI due to plasmid coding and the resulting deficiency in metal inserting chaperones might impair the correct insertion of hemeÊa3 and CuB because of a deficiency in metal inserting chaperones. This in turn might lead to differences in side chain orientation and to changes in the water network. However, slight changes might cause an increased accessibility of the active center for hydrogen peroxide, resulting in an increased catalase activity. The availability of chaperones and therefore the proposed structural reasons for the difference was improved by cloning the genes for the two metal inserting chaperones CtaG and Surf1c on the same plasmid together with SUÊI. This new rec. WT CcO showed in fact a reduced catalase activity. Another WT with a deletion in the chromosomal second, non expressing gene of SU I was analysed to prove plasmid coding as the reason for the difference of the ATCC WT and the rec. WT. This strain showed an increased kcat of the catalase activity as well, additionally pointing to a regulatory effect of the non expressed gene for SU I in the chromosome. To fathom the structural difference of the increased catalase activity, differential scanning calorimetry was used, but no significant difference in thermal stability between the ATCC WT CcO and the rec. WT CcO was detected. However, upon aging, the thermal stability of the rec. WT CcO declined faster than that of the ATCC WT CcO pointing to a decreased structural stability of the rec. WT CcO.
To characterize the catalase reaction, several known inhibitors were used to probe the contribution of the different metal cofactors in the catalase reaction. In addition variants in aromatic amino acids near the active center were constructed to conclude on a possible reaction mechanism of the catalase activity of CcO. These variants in combination with the wild type forms were analysed for radical signals by EPR-spectroscopy. A radical relevant for the catalase reaction of CcO was found in the F-intermediate of all variants and all wild type forms. This narrow 12 G radical signal was assigned to a porphyrine radical probably involved in the catalase reaction of CcO. Moreover, gas chromatography-mass spectrometry measurements were used to analyse isotopically labelled oxygen produced in the catalase reaction.
As a result of these experiments, a reaction cycle of the catalase activity of CcO is postulated and the structural difference between the ATCC and rec. WT CcO is outlined. The catalase activity appears to be a true catalase activity and not a "pseudocatalase" activity.
In Nervensystemen werden zahlreiche Informationen wahrgenommen und verarbeitet um ein adäquates Verhalten hervorzurufen. Für die Untersuchung der funktionellen Zusammenhänge hierbei wurden verschiedene Methoden entwickelt, die eine gezielte Manipulation neuronaler Prozesse ermöglichen. Durch Analyse der resultierenden Effekte können dabei synaptische Proteine, einzelne Neuronen oder neuronale Netzwerke funktionell charakterisiert werden. Bisherige Ansätze verfügen jedoch nur über eine geringe zeitliche und räumliche Auflösung oder erlauben lediglich eine eingeschränkte Anwendung im frei beweglichen Tier.
Diese Nachteile können durch die heterologe Expression von lichtgesteuerten, mikrobiellen Rhodopsinen zur gezielten Manipulation des Membranpotentials umgangen werden. So induziert die Photoaktivierung des Kationenkanals Channelrhodopsin 2 (ChR2; (Nagel et al., Curr Biol 2005)) eine Depolarisation, während die Chloridpumpe Halorhodopsin (NpHR; (Zhang et al., Nature 2007)) für die Hyperpolarisation verwendet werden kann. Dabei ermöglichen die schnellen Kinetiken der Rhodopsine eine zeitlich präzise Steuerung des Membranpotentials. Durch Auswahl geeigneter Promotoren ist zudem oftmals eine zell spezifische Expression möglich. Dieser Ansatz wird daher allgemein als Optogenetik bezeichnet.
In der vorliegenden Arbeit wurden zunächst konventionelle Techniken genutzt, um die Funktion von zwei assoziierten Proteinen eines Acetylcholin Rezeptors in C. elegans zu untersuchen. Des Weiteren wurden verschiedene Methoden für den Fadenwurm entwickelt und angewendet, die die Vorteile optogenetischer Techniken für die funktionelle Charakterisierung synaptischer Proteine und neuronaler Netzwerke nutzbar machen. Hierbei erlaubt die Transparenz von C. elegans die optogenetische Stimulation im lebenden Organismus unter nicht invasiven Bedingungen. Weitere Vorteile von C. elegans als neurobiologischem Modellorganismus liegen in seiner einfachen Handhabung (Hope, 1999) und der stereotypen Entwicklung seines Nervensystems mit bekannten anatomischen Ausprägungen (Sulston and Horvitz, Dev Biol 1977; Varshney et al., PLoS Comput Biol 2011; White et al., Philos Trans R Soc Lond B Biol Sci 1986). Durch ihre Häufigkeit und die experimentelle Zugänglichkeit wird hierbei die neuromuskuläre Synapse oftmals zur Erforschung der synaptischen Reizweiterleitung genutzt (Von Stetina et al., Int Rev Neurobiol 2006). Durch pharmakologische (Lewis et al., Neuroscience 1980; McIntire et al., Nature 1993; Miller et al., Proc Natl Acad Sci U S A 1996; Richmond and Jorgensen, Nat Neurosci 1999) und elektrische Stimulation (Richmond and Jorgensen, Nat Neurosci 1999) können dabei Defekte der Transmission hervorgehoben werden, während Verhaltensexperimente oder elektrophysiologische Messungen der post synaptischen Ströme in Muskelzellen eine quantitative Analyse ermöglichen (Richmond and Jorgensen, Nat Neurosci 1999).
Diese Methoden wurden für die funktionelle Charakterisierung von NRA 2 und NRA 4 verwendet, die beide als akzessorische Proteine zusammen mit dem Levamisol sensitiven Acetylcholin Rezeptor der Körperwandmuskelzellen aufgereinigt wurden (Gottschalk et al., EMBO J 2005). Dabei konnte gezeigt werden, dass NRA 2 und NRA 4 im Endoplasmatischen Retikulum (ER) der Muskelzellen einen Komplex bilden, der die Sensitivität von beiden nikotinischen Acetylcholin Rezeptoren gegenüber verschiedenen cholinergen Agonisten verändert. In diesem Zusammenhang wurde auch nachgewiesen, dass die Oberflächenexpression einzelner Untereinheiten der beiden Rezeptoren durch NRA 2/4 beeinflusst wird. Diese Resultate legen die Vermutung nahe, dass beide Proteine die Zusammensetzung der Rezeptoren und somit ihre pharmakologischen Eigenschaften modulieren. Denkbar ist dabei eine regulatorische Funktion bei der Assemblierung verschiedener Untereinheiten zu einem funktionellen Rezeptor oder bei der Kontrolle des ER Austritts von Rezeptoren mit bestimmter Zusammensetzung. In dieser Hinsicht konnte jedoch keine Interaktion von NRA 2/4 mit der Notch Signalkaskade nachgewiesen werden, wie sie für die homologen Proteine nicalin und NOMO in Vertebraten gezeigt wurde (Haffner et al., J Biol Chem 2007; Haffner et al., EMBO J 2004).
Für die Untersuchung synaptischer Proteine durch optogenetische Techniken wurde ChR2(H134R) selektiv in cholinergen oder GABAergen Motorneuronen exprimiert, um die akute und lichtgesteuerte Freisetzung des jeweiligen Neurotransmitters zu ermöglichen. Die resultierende Stimulation bzw. Inhibition von Muskelzellen wurde hierbei durch elektrophysiologische Messungen der post synaptischen Ströme und durch Analyse von Kontraktionen respektive Relaxationen untersucht. Dabei wurde gezeigt, dass Störungen der synaptischen Reizweiterleitung die Ausprägung und Dynamik dieser lichtinduzierten Effekte beeinflussen und dadurch charakterisiert werden können. So zeigten beispielsweise Mutanten von Synaptojanin und Endophilin nachlassende Effekte bei anhaltender oder wiederholter Stimulation, was durch die gestörte Regeneration synaptischer Vesikel erklärt werden kann (Harris et al., J Cell Biol 2000; Schuske et al., Neuron 2003; Verstreken et al., Neuron 2003).
Die hohe Sensitivität dieser Methode wurde im Nachfolgenden dazu verwendet, die Inhibition cholinerger Motorneuronen durch den metabotropen GABAB Rezeptor zu untersuchen, der in C. elegans aus den beiden Untereinheiten GBB 1 und GBB 2 gebildet wird (Dittman and Kaplan, J Neurosci 2008; Vashlishan et al., Neuron 2008). Dabei konnte zunächst gezeigt werden, dass diese heterosynaptische Inhibition verschiedene lokomotorische Verhaltensweisen der Tiere beeinflusst. Für die mechanistische Untersuchung wurden anschließend cholinerge Motorneuronen durch ChR2(H134R) photoaktiviert, während resultierende Kontraktionseffekte in Abhängigkeit von GBB 1/2 analysiert wurden. Um hierbei die Funktion von GBB 1/2 durch erhöhte GABA Konzentrationen hervorzuheben, wurden zusätzlich GABAerge Motorneuronen optogenetisch stimuliert oder die Wiederaufnahme von GABA aus dem synaptischen Spalt durch Mutation des Membran ständigen GABA Transporters blockiert. So konnte gezeigt werden, dass GBB 1/2 eine akute Inhibition der cholinergen Motorneuronen bewirken, was vermutlich für die Regulation von Bewegungsabläufen eine wichtige Rolle spielt. Die geringe Dynamik der GBB 1/2 induzierten Effekte deutet allerdings darauf hin, dass die synaptische Aktivität durch den metabotropen Rezeptor kaum nachhaltig moduliert wird.
In nachfolgenden Versuchen wurde die optogenetische Stimulation von Motorneuronen außerdem mit der elektronenmikroskopischen Analyse der präsynaptischen Feinstruktur kombiniert. Dadurch konnte die Dynamik der Exozytose und Endozytose synaptischer Vesikel (SV) in Abhängigkeit von neuronaler Aktivität untersucht werden. So wurde gezeigt, dass synaptische Vesikel nahe der aktiven Zone während einer 30 sekündigen Hyperstimulation nahezu komplett aufgebraucht waren. Die vollständige Regeneration der SV Pools benötigte anschließend etwa 12 Sekunden und erfolgte zunächst in der Peripherie der aktiven Zone, was auf eine laterale Heranführung der Vesikel schließen lässt. Nach etwa 20 Sekunden erholte sich ebenfalls die Wirksamkeit der Stimulation von Muskelzellen durch die Motorneuronen, was durch elektrophysiologische Messungen der photo induzierten post synaptischen Ströme gezeigt wurde. Während der Hyperstimulation bildeten sich außerdem große vesikuläre Strukturen, die sich anschließend nach etwa acht Sekunden wieder aufgelöst hatten. In Analogie zu vergleichbaren Experimenten in anderen Organismen liegt die Vermutung nahe, dass es sich dabei um Zwischenprodukte der so genannten Bulk Phase Endozytose handelt, die das Clathrin abhängige Recycling von synaptischen Vesikeln bei starker neuronaler Aktivität ergänzt (Heuser and Reese, J Cell Biol 1973; Miller and Heuser, J Cell Biol 1984; Richards et al., Neuron 2000). Bemerkenswerterweise war der Abbau der vesikulären Strukturen in Synaptojanin und Endophilin defizienten Tieren stark verzögert. Denkbar ist, dass beide Proteine für die Synthese von synaptischen Vesikeln aus den vesikulären Zwischenprodukten der Bulk Phase Endozytose wichtig sind, analog zur ihrer Funktion bei der Clathrin abhängigen Endozytose an der Plasmamembran.
Durch die zielgerichtete Manipulation der Zellaktivität ermöglichen optogenetische Techniken außerdem die funktionelle Charakterisierung von Neuronen und neuronalen Netzwerken. Um die zelluläre Spezifität dieses Ansatzes zu erhöhen, wurde ein Tracking System entwickelt das die Position frei beweglicher Tiere in Echtzeit bestimmt und nachverfolgt. Dadurch konnte die Photoaktivierung optogenetischer Proteine auf definierte Bereiche der Fadenwürmer und somit auf ausgewählte Neuronen innerhalb der Expressionsmuster von verwendeten Promotoren eingeschränkt werden. Des Weiteren ermöglichte hierbei die Auswertung translatorischer Parameter die Analyse verschiedener lokomotorischer Merkmale wie Geschwindigkeit, Bewegungsbahn oder Ausprägung der Körperbiegungen. Dieses System wurde beispielhaft für die konzertierte Photoaktivierung durch ChR2(H134R) bzw. Photoinhibition durch MAC von zwei verschiedenen Gruppen von Neuronen angewendet, um die Integration mechanosensorischer Informationen durch Command Interneuronen zu untersuchen. In diesem Zusammenhang wurde zudem eine Rekombinase basierte Methode für optogenetische Proteine adaptiert, die die Transkription auf die zelluläre Schnittmenge von zwei verschiedenen Promotoren einschränkt und somit die Spezifität der Expression erhöht. Idealerweise kann dieser Ansatz außerdem mit der gezielten Photoaktivierung kombiniert werden, um die zelluläre Selektivität optogenetischer Anwendungen weiter zu verbessern.
Weiterhin ist die Anwendung optogenetischer Techniken bisher durch intrinsische Eigenschaften der verwendeten Rhodopsine auf die relativ kurzzeitige Manipulation des Membranpotentials von Zellen beschränkt. So benötigt ChR2 durch die schnelle Schließung seines offenen Kanals eine kontinuierliche Photoaktivierung, um eine andauernde Depolarisation hervorzurufen. Dies ist jedoch potentiell mit phototoxischen und – besonders bei C. elegans – phototaktischen Nebeneffekten verbunden. Deswegen wurden diverse Mutanten von ChR2 mit stark verlangsamter Inaktivierung (Berndt et al., Nat Neurosci 2009) für ihren Nutzen zur Langzeit Stimulation von erregbaren Zellen im Nematode getestet. Dabei wurde gezeigt, dass ChR2(C128S) durch einen kurzen Photostimulus mit vergleichsweise niedriger Intensität eine anhaltende Depolarisation über mehrere Minuten auslösen kann. Die wiederholte Stimulation in ASJ Neuronen ermöglichte zudem eine langzeitige Depolarisation über mehrere Tage, wodurch die genetisch veranlagte Entwicklung von Tieren manipuliert werden konnte. Durch gezielte Punktmutation konnten außerdem relevante Eigenschaften von ChR2(C128S) für die Langzeit Stimulation weiter verbessert werden.
Als weiteres optogenetisches Werkzeug wurde zudem die Photoaktivierbare Adenylatzyklase alpha (PACa) aus Euglena gracilis (Iseki et al., Nature 2002; Ntefidou et al., Plant Physiol 2003; Schroder-Lang et al., Nat Methods 2007) für die akute und lichtgetriebene Synthese des sekundären Botenstoffs cAMP in C. elegans etabliert. Die Photoaktivierung von PACa in cholinergen Motorneuronen verstärkte dabei die Neurotransmitterfreisetzung und induzierte hyperlokomotorische Phänotypen, vergleichbar zu Mutanten mit erhöhten cAMP Konzentrationen.
Zusammengefasst wurden diverse optogenetische Techniken für C. elegans entwickelt und optimiert, die die zellspezifische und nicht invasive Manipulation des Membranpotentials beziehungsweise die Synthese des sekundären Botenstoffs cAMP durch Licht im frei beweglichen Tier ermöglichen. Diese Methoden können zur gezielten Störung neuronaler Aktivität angewendet werden, um dadurch neurobiologische Fragestellungen im Fadenwurm zu untersuchen. Dies wurde beispielhaft für die Erforschung der synaptischen Reizweiterleitung und die funktionelle Analyse neuronaler Netzwerke demonstriert. Denkbar ist außerdem, diese für C. elegans etablierten Methoden vergleichbar in anderen Modellorganismen anzuwenden. So sind die Fruchtfliege ebenso wie der Zebrafisch Embryo bereits für optogenetische Techniken erprobt (Arrenberg et al., Proc Natl Acad Sci U S A 2009; Schroll et al., Curr Biol 2006). Für Säugetiere wie die Maus, die Ratte und den Makaken wurden zudem bereits Ansätze entwickelt, die die gezielte Photostimulation in lebenden und frei beweglichen Tieren ermöglichen (Han et al., Neuron 2009; Wentz et al., J Neural Eng 2011; Yizhar et al., Nature 2011; Zhang et al., Nat Rev Neurosci 2007).
The translocation of nuclear-encoded precursor proteins into chloroplasts is a highly ordered process involving the action of several components to regulate this molecular ensemble. Not only GTP hydrolysis and GDP release but also the phosphorylation of TOC GTPases is a widely discussed mechanism to regulate protein import. The receptor component (Toc34) and its isoform of A. thaliana (atToc33) were found to be regulated by phosphorylation. Although the phosphorylation of Toc33 is already known for several years, several questions regarding the molecular components involved in the regulation of the phosphorylation process, precisely what is the protein kinase and where this kinase is initially localized, so far remained unclear.
This thesis aimed at the defining of the phosphorylation status of TOC GTPases in monomeric and/or dimeric states, the identification of the nature of Toc33-PK (protein kinase), and in the same context it aimed at gaining first insights into the physiological significance of Toc33 phosphorylation. To this end, (I) An in vitro and in vivo system for investigating of TOC GTPases Phosphorylation (in monomeric or dimeric state) was developed. Since no information is available about the phosphorylation status of the Toc159 isoforms, the second receptor of the TOC complex, it was interesting to investigate whether these isoforms undergo phosphorylation or not. The results indicated that atToc159 isoforms are able to be phosphorylated by the kinase activity in purified outer envelope membranes (OEMs) of pea, but not atToc132. Moreover, an artificial dimer of psToc34 based on the interaction of a C-terminally fused leucine zipper was not phosphorylated. This result reflected the inability of the OEM kinase to phosphorylate the dimers of TOC GTPases. Also, In vivo labeling of atToc33 was developed and occurred in a dose-dependent manner. Therefore, this results evidenced that in vitro phosphorylation of atToc33 (both endogenous wild type and recombinant expressed proteins) is not artificial labeling but represents a physiological relevance. CD (circular dichroism) measurements revealed that recombinant GTPase domain of atToc33 is preferentially phosphorylated in its folded state. Therefore, it could be suggested that folding of atToc33rec is a prerequisite for its phosphorylation and the phosphorylation event occurs as a posttranslational modification most likely after insertion of Toc33 (Toc34) into the OE of chloroplasts.
Secondly, (II) Isolation and identification of Toc33-PK from OEMs of chloroplasts was performed. Four independent strategies were developed to identify the Toc33-protein kinase: UV-induced and chemically-based crosslinking, different applied chromatographic techniques, identification of PK-Toc33 interaction by means of HDN-PAGE (histidine- and deoxycholate-based native PAGE), and finally mass spectrometric approaches were performed on fractions including the potential kinase activity. UV-induced crosslinking procedure was developed and resulted in covalent bonding of nine proteins to [a-32P] ATP, while chemically-based one was not significant. The applied chromatographic and HDN-PAGE approaches, including mass spectrometry, have revealed the identification of 13 protein kinases. Of these identified kinases, phototropin2 (Phot2, AT5G58140), leucine-rich repeat PK (LRR-PK, AT4G28650.1), and receptor-like transmembrane PK (RLK, AT5G56040.2) were selected as the most promising candidates (ca. kinase type and one transmembrane helix for membrane localization).
(III) The physiological significance of Toc33 phosphoryation was shown to link this process with the environmental changes (especially, the light conditions). Identification of chloroplast OE-located PKs performed by nLC-MALDI-MS/MS resulted in the detection of Phot2. Furthermore, the subcellular localization of Phot2 in OEM of chloroplasts was confirmed by immunoblotting experiments using a-Phot2 antibody. The kinase activity of Phot2 towards TOC GTPases was characterized and revealed that fused GST-KD (kinase domain) protein able to specifically phosphorylate atToc33rec, but not atToc159rec. Also, endogenous atPhot2 was upregulated and heavily detected in the ppi1-S181A plant line (where serine to alanine exchange was performed to abolish the phosphorylation of atToc33). Hence, we suggested that certain signal cascades may directly or indirectly link Toc33 receptor phosphorylation, protein levels of Phot2 (as promising PK candidate), and irradiation conditions (as an inducing signal of the subsequent phosphorylation events). Light-dependent phosphorylation of Toc33 was shown either after de-etiolation conditions or after high light intensities of blue light was performed. Therefore, phosphorylation of Toc33 might be identified as an external regulatory signal to regulate preproteins import into chloroplasts in response to environmental conditions (e.g. light changes) or as a signal of chloroplast biogenesis.
The adaptive immune system of jawed vertebrates is based on recognition and elimination of cells that are either invaded by intracellular pathogens or malignantly transformed. One essential component of these processes is the cell surface presentation of antigenic peptides via major histocompatibility complex (MHC) class I molecules to cytotoxic T-cells (CTLs). Cells degrade defective ribosomal products and misfolded or unwanted proteins by the ubiquitin-proteasome pathway. The resulting degradation products are recognized and translocated by the transporter associated with antigen processing (TAP) into the endoplasmic reticulum (ER) lumen, where they are loaded onto MHC I molecules. Assembled peptide-MHC complexes are then shuttled by the secretory pathway to the cell surface for antigen presentation to CTLs, leading in the case of viral infection or malignant transformation to lysis and apoptosis of the target cell. Due to the fact that the TAP complex represents a key control point within the antigen presentation pathway, several viruses have evolved sophisticated strategies to evade immune surveillance by interfering with TAP function.
Detailed studies of the TAP mechanism or its viral inhibition have been severely impeded by difficulties in expressing sufficient amounts of functional heterodimeric TAP complex. Thus, the overexpression of TAP in the methylotrophic yeast Pichia pastoris was established for functional analysis of this important ABC complex. Biomass production was scaled up by fermentation using classical batch and feed methods. Extensive screening of optimal solubilization and purification conditions allowed the isolation of the heterodimeric transport complex. Notably, only the very mild detergent digitonin preserved TAP function. Hereby, the optimal solubilization and purification strategy yielded in 30 mg TAP transporter per liter culture. Remarkably, the protein amount was 50-fold increased compared to previously described expression/purification in cultured insect cells.
The high yield and quality of TAP produced in P. pastoris allowed an extensive analysis of substrate binding and transport kinetics of the transport complex in the membrane, its solubilized and purified state, as well as the reconstituted state. Thereby, a strong and direct effect of the lipid bilayer on ATP hydrolysis and peptide transport was discovered. These important results were extended further by successful functional reconstitution of the antigen translocation machinery in different lipid environments. For the first time, a stimulation of the transport activity by phosphatidylinositol (PI) and phosphatidylethanolamine (PE) was observed, whereas cholesterol was identified as an inhibitor of TAP activity.
Purification of TAP and subsequent thin-layer chromatography (TLC)/liquid chromatography Fourier transform-mass spectrometry (LC FT-MS) fingerprinting of residual lipids exhibited specifically associated glycerophospholipids; mainly PC, PE, and PI species. Strikingly, these lipids not only represent the primary class of phospholipids of the ER but were also shown to be essential for functional reactivation of delipidated, and thus inactive, TAP. The results demonstrate that transport of antigenic peptides by the ABC transporter TAP strictly requires specific glycerophospholipids.
In addition to the biochemical characterization of heterologous produced TAP, the soluble domain of the viral inhibitor US6 from human cytomegalovirus was expressed in E. coli. Optimization of the purification and refolding strategy yielded in functional protein, with a 35-fold increased protein amount compared to previous purification procedures. Protein activity was analyzed by specific inhibition of ATP binding to TAP. Furthermore, high protein yields allowed detailed investigation of TAP-dependent spatial and mechanistic separation of MHC I restricted cross-presentation in professional antigen presenting cells (pAPC).
The ubiquinol:cytochrome c oxidoreductase is a key component of several aerobic respiratory chains in different organisms. It is an integral membrane protein complex, made up of three catalytic subunits (cytochrome b, cytochrome c1 and Rieske iron sulphur protein) and up to eight additional subunits in mitochondria. The complex oxidizes one quinol molecules and reduces two cytochrome c during the Q cycle, originally described by Peter Mitchell. Electrons are split between the low and the high potential chain and protons are released on the positive side of the membrane, increasing the protonmotive force needed by the ATP-synthase for energy transduction. The cytochrome bc1 complex from P. denitrificans is a perfect model for structural and functional studies. Bacteria are easy to grow and the genetic material is readily accessible for genetic manipulation. Moreover, the P. denitrificans aerobic respiratory chain is very close to the mitochondrial one: the complexes involved in electron transfer resemble the ones found in mitochondria, but lack most of the additional subunits. As a unique feature, P. denitrificans has a strongly acidic domain at the N-terminal region of the cytochrome c1, a sequence of 150 aminoacids which does not correlate with any known protein. An analogous composition can be found in the eukaryotic cytochrome bc1 complex as a part of an accessory subunit, proposed to be involved in facilitating electron transfer between the complex and the electron acceptor cytochrome c. In order to study the function of this domain in the P. denitrificans cytochrome bc1 complex, a deletion mutant has been previously cloned and modified with an affinity tag as a C-terminal extension of cytochrome b. The complex is purified by affinity chromatography and characterized by steady-state kinetics using not only horse heart cytochrome c but also the endogenous electron acceptor, the membrane bound cytochrome c552, employed here as a soluble fragment. Steady–state kinetics indicate that the deletion of the long acidic domain had effects neither on the turnover rate nor on the apparent affinity for the substrate. To understand wether the deletion affects the reaction between the cytochrome bc1 complex and the substrate, laser flash photolysis experiments are performed, showing that the interaction observed was not changed in the complex missing the acidic domain. The results presented in this work confirm the ones previously obtained by Julia Janzon using soluble fragments of the same interaction partners. The deletion, however, affected the oligomerization state of the complex, as shown by LILBID (Laser Induced Liquid Bead Ion Desorption) analysis. The wild type complex has a tetrameric structure, better described as a “dimer of dimers”. The deletion of the acidic domain on the cytochrome c1 results in the separation of the two dimers, yielding the canonical dimer. Therefore, the complex deleted in the acidic domain is used for cloning and expression of a heterodimeric complex, containing an inactivating mutation in the quinol oxidation site in only one monomer, thus allowing a selective switch-off for half the complex. Such a complex is needed for the verification of an internal regulation mechanism, the half-of-the-sites reactivity. According to it, the dimeric structure of the cytochrome bc1 complex has functional implications, since the two monomers can communicate and work in a coordinated manner. This approach confirms that substrate oxidation does effectively take place only in one of the two monomers constituting the dimer, and that the binding of substrate at the Qo and Qi site regulates the switch between active and inactive monomer. Moreover, this mechanism works also as an effective protection against the reaction of quinone intermediates with oxygen and the formation of reactive oxygen species (ROS), responsable for cellular aging. The motion of the ISP head domain is also addressed in this work; in particular the mechanism which regulates the movements towards the cytochrome c1 and the electron bifurcation at the quinol oxidation site. Laser flash kinetics in presence of several inhibitors and the substrate allow studying the response of the ISP to the binding of different species at the quinol oxidation site. The binding of ligand at the Qo site in the complex triggers the conformational switch in the ISP head domain, supporting the mechanism proposed in the literature according to which the Qo site is able to “sense” the presence of substrate and transfer the information to the ISP, regulating its mobility. The internal electron pathway between the ISP and the cytochrome c1 has been analyzed also by stopped-flow kinetics, in presence and absence of inhibitors. The results indicate that two kinetic phases describe the reduction of cytochrome c1 by the ISP, and a model for the simulation of the data is proposed.
Employing NMR spectroscopy, it is not only possible to calculate the three dimensional structures of single proteins, but also to study dynamics and conformational changes of protein-complexes. In fact that is an important aspect, since the protein function depends on dynamics and interactions with other molecules. Therefore the study of protein-protein interactions is of highest importance for a better understanding of biological processes. Based on NMR methods, in this thesis we were able to determine protein-protein interactions within the enterobacterial Rcs signalling complex which is regulated via a phosphorelay. Originally identified as regulator of capsule synthesis, the Rcs phosphorelay is now considered to be implicated in stress response caused by disturbances in the peptidoglycan layer. Beyond that the Rcs system is involved in multiplex transcriptional networks including cell division, motility, biofilm formation and virulence. Because of such global nature and its extraordinary structural organisation involving membrane integrated sensor proteins (RcsC, RcsD), coactivators (RcsF, RcsA) and a transcription factor (RcsB), the Rcs system is one of the most remarkable phosphorelays in the family of enterobacteriacaea. During the complex phosphotransfer the histidine phosphotransferase (HPt) domain of the intermediary RcsD protein mediates the phosphotransfer between RcsC and RcsB, and probably modulates the phosphorylation state of the response regulator RcsB. Therefore the present work has been focused on the interface between RcsD and RcsB in more detail. In the first part of the thesis a new domain within the RcsD protein has been identified and structurally analysed by liquid NMR spectroscopy. RcsD is an inner membrane bound hybrid sensor like-kinase composed of a periplasmic sensor domain and a cytoplasmic portion. The cytoplasmic part contains the histidine like-kinase (HK) domain and the histidine phosphotransferase (HPt) domain. By analysis of the secondary structure in more detail, it was shown here that the two domains are intermitted by an additional 13.3 kDa domain. Corresponding to the position of the ABL (α−β−loop) domain of RcsC, located C-terminal to the RcsC-HK domain, the new identified domain was named RcsD-ABL. The central structural element of RcsD-ABL is a β-sheet composed of six strands with a β1−β2−β3−β4−β6−β5 topology and surrounded by two α-helices α1 and α2. In the second part of the thesis, RcsD-ABL is identified as a binding domain for the response regulator RcsB by NMR titration experiments. Such a binding domain for a response regulator has so far only been described for the histidine kinase CheA. In reportergene assays with β-galactosidase and ONPG as substrate it was shown that overexpression of RcsD-ABL in high amounts inhibited binding of RcsB to its target promoter. The β-galactosidase activity was reduced by 80 % with respect to cells carrying no plasmid encoding RcsD-ABL. The mapping of the binding interface was successfully achieved by chemical shift perturbations, a fast mapping protocol and selective labelling. It was shown that the interaction between RcsD-ABL and RcsB takes place via a binding interface comprising mainly the two α-helices of RcsD-ABL and the α-helices α7, α8 and α10 in the effector domain of RcsB. In the third part of the thesis, the interaction of RcsB with RcsD-ABL was related to that with RcsD-HPt. Using NMR titration experiments and ITC measurements, a comparison of the binding constants (Kd) of RcsB interacting either with the isolated RcsD-ABL (2 PM) or the isolated RcsDHPt domain (40 PM) revealed a higher affinity of RcsD-ABL to RcsB. A conjugate of RcsD-ABL-HPt interacting with RcsB decreased the Kd in the one-site fitting mode to 10 PM. However, the two-site fitting mode applied for RcsD-ABL-HPt/RcsB interaction resulted in a Kd (RcsD-ABL) of 2 PM and a Kd (RcsD-HPt) of 8 PM, indicating that RcsD-ABL enhances the binding of RcsD-HPt to RcsB. In the last part of the thesis, it was partly possible together with the data obtained from NMR titration experiments, PRE measurements and a HADDOCK protocol to develop a geometrical model for the interaction of RcsD with RcsB. In this model the receiver domain of RcsB interacts with the RcsD-HPt domain and the RcsB effector domain interacts with the RcsD-ABL domain. These results lead to surprising insights on the regulation of phosphorelays, since normally the effector domain binds to DNA. Here the effector domain is recognized by the newly identified RcsD-ABL domain. Prospectively, further investigations of phosphorylation affects and mutational studies will be of great interest.
Genes coding for membrane proteins make up 25%-30% of the genome in most organisms. Membrane proteins play an important role in cell functioning and their importance is enhanced by the fact that a large number of drugs are targeted at membrane proteins. Paradoxically, experimentally determined structures of membrane protein correspond to only about 1.7% of protein structures deposited in the protein data bank (PDB). This is largely due to the fact that membrane proteins are difficult to deal with owing to their amphipathic nature. The low abundance of membrane proteins in native tissue makes heterologous overexpression of these genes a necessity. This thesis work aimed at heterologous production of several secondary active transporter proteins for structural and functional characterizations and establishing alternative strategies to overcome the obstacles associated with heterologous overproduction. Four members of the heavy metal transporting cation diffusion facilitator (CDF) family from S. typhimurium and A. aeolicus were heterologously overproduced in E. coli and functionally characterized by an in vivo complementation assay using the zinc transport deficient E. coli GG48 strain. Out of these four, Aq_2073 from A. aeolicus was produced in large scale with substantial yield and purity sufficient to carry out structural studies. After extensive stability studies with different detergents, pHs and temperatures, the protein was subjected to 3D and 2D crystallization trials. Several C- terminal truncated constructs were made and the simultaneous crystallization screenings were carried out. These resulted in initial needle like crystals in 3D crystallization trials or optimum sized vesicles with crystalline patches in 2D crystallization trials but no obvious crystal. The protein showed significant increase in melting temperature in the presence of cadmium, when tested by differential scanning calorimetry. Another transporter, STM3880 of the potassium uptake permease (KUP) family from S. typhimurium, was heterologously overproduced in E. coli, purified by affinity chromatography, reconstituted into artificial liposome and functionally characterized by solid supported membrane based electrophysiology. In order to establish alternative expression strategies, continuous exchange cell free expression (CECF) of proteins from four different families was carried out. This method found to be aptly complementing the cell-based production approach. Targets from resistance to homoserine/threonine (RhtB) family not expressing in vivo could be expressed and purified using CECF. STM1781 of the sulfate permease (SulP) family was expressed, purified and characterized for stability while the cell-based production resulted in extensive degradation. PF0780 of multidrug/oligosaccharidyllipid/polysaccharide flippase (MOP) family was also purified to homogeneity and the stability was comparable to in vivo produced protein. Moreover, the effect of maltose binding protein (MBP) fusion at N-terminus on production and membrane integration was tested with three selected targets. The analysis revealed decreased yields in the presence of MBP if the protein had both termini in the cytoplasm. This work succeed in heterologously overproducing and establishing purification protocols for several secondary active transporters aiming at structural and functional characterization in a structural genomics framework. It also showed that integration of alternative strategies, like employing both cell-based and cell-free heterologous expression systems, expands the overall expression space coverage and in turn increases the chance of success of a structural genomics styled project.