Biologische Hochschulschriften (Goethe-Universität; nur lokal zugänglich)
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The adaptive immune system protects against daily infections and malignant transformation. In this, the translocation of antigenic peptides by the transporter associated with antigen processing (TAP) into the ER lumen is an essential step in the antigen presentation by MHC I molecules. The heterodimeric ATP-binding cassette transporter (ABC) TAP consist of the two halftransporters TAP1 and TAP2. Each monomer contains an N-terminal transmembrane domain (TMD) and a conserved C-terminal nucleotide-binding domain (NBD). Together, the TMDs build the translocation core and the NBDs bind and hydrolyze ATP, energizing the peptide transport. TAP features an asymmetry in the two ATP-binding sites that are built of several conserved motifs. One motif is the D-loop with the consensus sequence SALD. The highly conserved aspartate of the D-loop of TAP1 reaches into the canonic ATP-binding site and contacts the Walker A motif and the H-loop of the opposite NBD, while the Asp of D-loop of TAP2 is part of the non-canonic ATP-binding site.
To examine this ABC transport complex in mechanistic detail, a purification and reconstitution procedure was established with the function of TAP being preserved. The heterodimeric TAP complex was purified via a His10-tag at TAP1 in a 1:1 ratio of the subunits. Nucleotide binding to the purified transporter was elucidated by tryptophan quenching assays and the affinity constants for MgADP and MgATP were determined to be 1.0 μM and 0.7 μM, respectevely. In addition, the TAP complex shows strict coupling between peptide binding and ATP hydrolysis, revealing no basal ATPase activity in the absence of peptides. Furthermore, TAP was reconstituted into proteoliposomes and the activity was tested by peptide transport and ATP hydrolysis. Interestingly, the kinetic parameters of the transporter in the reconstituted state are comparable to the data gained for TAP in microsomes.
To characterize the functional importance of the D-loop, D-loop mutants of either TAP1 or TAP2 were analyzed. Strikingly, TAP containing a mutated D-loop in TAP1 (D674A) shows an ATP-hydrolysis independent peptide translocation. Accordingly, the MHC I surface expression is similar to the wildtype situation. However, the same mutation in TAP2 (D638A) results in an ATPase dependent peptide transport similar to wildtype, whereas TAP containing mutations in both subunits leads to an inactive transporter. Although all D-loop mutants showed no altered peptide binding activity, the TAP1 mutant is inactive in peptide-stimulated ATPase activity. Strikingly, ATP or ADP binding is strictly required for the peptide translocation. Experiments carried out in proteoliposomes demonstrate that wildtype TAP can export peptides against their gradient when low peptide concentrations are offered. In contrast, the D674A mutant can facilitate peptide translocation along their concentration gradient in the two directions. At high peptide concentrations, TAP is trapped in a transport incompetent state induced by trans-inhibition. In conclusion, a TAP mutant that uncouples solute translocation from ATP hydrolysis was created. Since this passive substrate movement is strictly dependent on binding of ATP or ADP, an active transporter was turned into a “nucleotide-gated facilitator”.
In a cysteine cross-linking approach the conformational changes of TAP during peptide transport and the flexibility of the nucleotide binding domains were examined. Single cysteines were introduced in the D-loops of TAP1 and TAP2. Cross-linking by copper-phenantroline (CuPhe) was possible for all combinations. However, by adding ATP, ADP or peptide to the TAP complex no differences in the cross-linking efficiency were detected. By CuPhe cross-linking TAP was trapped in a conformation, in which the peptide binding site was not accessible. To complete a transport cycle, a flexibility of at least 17.8 Å of the NBDs is needed, since TAP cross-linked by CuPhe (2.0 Å) or bismaleimidoethane (BMOE, 8.0 Å) was transport inactive but when TAP was cross-linked by 1,11-bismaleimido-triethyleneglycol (BM[PEG]3, 17.8 Å) transport activity was preserved.
An exciting in vivo function of ATP-sensitive potassium channels in substantia nigra dopamine neurons Ð Implications for burst firing and novelty coding ÐPhasic burst activity is a key feature of dopamine (DA) midbrain neurons. This particular pattern of excitation of DA neurons occurs via a synaptically triggered transition from low-frequency background spiking to transient high-frequency discharges. Burst-firing mediated phasic DA release is critical for flexible switching of behavioural strategies in response to unexpected rewards, novelty and other salient stimuli. However, the cellular and molecular bases of burst signalling in distinct DA subpopulations of the substantia nigra (SN) or the ventral tegmental area (VTA) are unknown.
DA neuron excitability is controlled by synaptic network inputs, neurotransmitter receptors and ion channels, which generate action potentials and determine frequency and pattern of electrical activity in a complex interplay. ATP-sensitive potassium (K-ATP) channels are widely expressed throughout the brain, where in most cases they are believed to act as metabolically-controlled 'excitation brakes' by matching excitability to cellular energy states. However, their precise physiological in vivo function in DA neurons remains elusive.
To study burst firing and the underlying ionic mechanisms with single cell resolution, in vivo single-unit recordings were combined with juxtacellular neurobiotin labelling as well as immunohistochemical and anatomical identification of individual DA neurons. In vivo recordings were performed in adult isoflurane-anaesthetised wildtype (WT) and global K-ATP channel knockout mice, lacking the pore forming Kir6.2 subunit (Kir6.2-/-). In addition, DA cell-selective functional silencing of K-ATP channel activity in vivo was established using virus-mediated expression of dominant-negative Kir6.2 subunits. Careful control experiments ruled out any significant contributions from nonDA neurons as transduction was effectively limited to SN DA neurons rather than affecting those cells that innervate them. Virus-based K-ATP channel silencing in combination with juxtacellular recording and labelling was achieved to define the electrophysiological phenotype of individually identified, virally-transduced DA neurons in vivo.
Single-unit recordings revealed that K-ATP channels Ð in contrast to their conventional hyperpolarising role Ð in a subpopulation of DA neurons located in the medial SN (m-SN) act as cell-type selective gates for excitatory burst firing in vivo. The percentage of spikes in bursts was threefold reduced in Kir6.2-/- compared to WT mice. Classification of firing patterns based on visual inspection of autocorrelation histograms and on a newly developed spike-train-model confirmed the dramatic shift from phasic burst to tonic single-spike oscillatory firing in Kir6.2-/-. This significant decrease of burstiness was selective for m-SN DA neurons and was not exhibited by DA cells in the lateral SN or VTA. Virus-based K-ATP channel silencing in vivo unequivocally demonstrated that the activity of postsynaptic K-ATP channels was sufficient to disrupt bursting in m-SN DA neuron subtypes. Patch-clamp recordings in brain slices indicated an essential role of K-ATP channels for NMDA-mediated in vitro bursting. In accordance with previous studies in DA midbrain neurons, NMDA receptor stimulation triggered burst-like firing in m-SN DA cells in vitro, but only when K-ATP channels were co-activated in these neurons.
K-ATP channel-gated burst firing in m-SN DA neurons might be functionally relevant in awake, freely moving mice. To explore the behavioural consequences of SN DA neuron subtype-selective K-ATP channel suppression, spontaneous open field (OF) behaviour of mice with bilateral K-ATP silencing across the whole SN (medial + lateral) or in only the lateral SN was tested. Analysis of WT and global Kir6.2-/- mice showed reduced exploratory locomotor activity of Kir6.2-/- in a novel OF environment. Remarkably, K-ATP channel silencing in m-SN DA neurons phenocopied this novelty-exploration deficit, indicating that K-ATP channel-gated burst firing in medial but not lateral SN DA neurons is crucial for WT-like novelty-dependent exploratory behaviour.
In summary, a novel role of K-ATP channels in promoting the excitatory switch from tonic to phasic firing in vivo in a cell-type specific manner was discovered. The present PhD thesis provides several important insights into the pivotal function of K-ATP channels in medial SN DA cells, which project to the dorsomedial striatum, for burst firing and its important consequences for context-dependent exploratory behaviour.
In collaboration with two other research groups transcriptional up-regulation of K-ATP channel and NMDA receptor subunits and high levels of in vivo burst firing were detected in surviving SN DA neurons from Parkinson's disease (PD) patients Ð providing a potential link of K-ATP channel activity to neurodegenerative pathomechanisms of PD. Using high-resolution fMRI imaging another study in humans has recently identified distinct DA midbrain regions that are preferentially activated by either reward or novelty. Taken together, these human data and the results of the present PhD thesis suggest that burst-gating K-ATP channel function in SN DA neurons impacts on phenotypes in disease as well as in health.
The environmental impact of climate change is meanwhile not only discussed in the scientific community but also in the general public. However, little is known about the interaction between climate change and pollutants like pesticides. A combination of multiple stressors (e.g. temperature, pollutants, predators) may lead to severe alterations for organisms such as changes in time of reproduction, reproductive success and growth performance, mortality and geographic distribution. The questions if aquatic organisms tend to react more sensitive towards incidents under climate change conditions remains. Therefore, within the present thesis the aquatic ecotoxicological profile of the fungicide pyrimethanil, as an exemplarily anthropogenic used contaminant, was examined.
A large test battery of ecotoxicological standard tests and supplement bioassays with non-model species was conducted to investigate if species-specific or life stage-specific differences occur or if temperature alteration may change the impact of the fungicide. Two of the most sensitive species (Chironomus riparius and Daphnia magna) were used to investigate the acute and chronic thermal dependence of pyrimethanil effects. The results clearly depict that the ecotoxicity of pyrimethanil at optimal thermal conditions did not depend on the trophic level, but was species-specific. With regard to EC10 values the acute pyrimethanil toxicity on C. riparius increased with higher temperature (6.78 mg L-1 at 14°C and 3.06 mg L-1 at 26°C). The chronic response of D. magna to the NOEC (no observed effect concentration) of the fungicide (0.5 mg L-1) was examined in an experiment which lasted for several generations under three simulated near-natural temperature regimes (‘cold year, today’ (11 to 22.7°C), ‘warm year, today’ (14 to 25.2°C) and ‘warm year, 2080’ (16.5 to 28.1°C)). A pyrimethanil-induced mortality increase was buffered by the strongly related increase of the general reproductive capacity, while population growth was stronger influenced by temperature than by the fungicide. At a further pyrimethanil concentration (LOEC – lowest observed effect concentration: 1 mg L-1), a second generation could not be established by D. magna under all thermal regimes.
Besides daphnids, the midge C. riparius was used for a second multigeneration study. In a bifactorial test design it was tested if climate change conditions alter or affect the impact of a low fungicide concentration on life history and genetic diversity. The NOAEC/2 (half of the no observed adverse effect concentration derived from a standard toxicity test) was used as a low pyrimethanil concentration to which laboratory populations of the midges were chronically exposed under the mentioned temperature scenarios. During the 140-day-multigeneration study, survival, emergence, reproduction, population growth, and genetic diversity of C. riparius were analyzed. The results reveal that high temperatures and pyrimethanil act synergistically on life history parameters of C. riparius. In simulated present-day scenarios, a NOAEC/2 of pyrimethanil provoked only slight to moderate beneficial or adverse effects. In contrast, an exposure to a NOAEC/2 concentration of pyrimethanil at a thermal situation likely for a summer under the future expactations uncovered adverse effects on mortality and population growth rate. In addition, genetic diversity was considerably reduced by pyrimethanil in the ‘warm year, 2080’ scenario, but only slightly under current climatic conditions. The multigeneration studies under near-natural thermal conditions indicate that not only the impact of climate change, but also low concentrations of pesticides may pose a reasonable risk for aquatic invertebrates in the future. This clearly shows that thermal and multigenerational effects should be considered when appraising the ecotoxicity of pesticides and assessing their future risk for the environment.
In addition to temperature further multiple abiotic and biotic stressors alterate pollutant effects. Moreover, to better discriminate and understand the intrinsic and environmental correlates of changing aquatic ecosystems, it was experimentally unraveled how the effects of a low-dose of pyrimethanil on daphnids becomes modified by different temperatures (15°C, 20°C, 25°C) and in the presence/ absence of predator kairomones of Chaoborus flavicans larvae. The usage of a fractional multifactorial test design provided the possibility to investigate the individual growth, reproduction and population growth rate of Daphnia pulex via different exposure routes to the fungicide pyrimethanil at an environmentally relevant concentration (0.05 mg L-1) - either directly (via the water phase), indirectly (via algae food), dually (via water and food) or for multiple generations (fungicide treated source population).
The number of neonates increased with increasing temperatures. At a temperature of 25°C no significant differences between the individual treatment groups were observed although the growth was overall inhibited due to pyrimethanil. Besides, at 15 and 20°C it is obvious that daphnids which were fed with contaminated algae had the lowest reproduction and growth rate. The obtained results clearly demonstrate that multiple stress factors can modify the response of daphnids to pollutants. The exposure routes of the contaminant are of minor importance, while temperature and the presence of a predator are the dominant factors impacting the reproduction of D. pulex. It can be concluded that low concentrations of pyrimethanil may disturb the zooplankton community at suboptimal temperature conditions, but the effects will become masked if chaoborid larvae are present. Therefore it seems necessary to observe prospectively if the combination of several stress factors like pesticide exposure and suboptimal temperature may influence the life history and sensitivity of several aquatic invertebrates differently.
Besides standard test organisms it is inevitable to conduct test with aquatic invertebrate which are not yet considered regularly in ecotoxicological experiments. For example molluscs represent one of the largest phyla of macroinvertebrates with more than 100.000 species, being ecologically and economically important. Therefore, within the present study embryo, juvenile, half- and full-life cycle toxicity tests with the snail Physella acuta were performed to investigate the impact of pollutants on various life stages. Different concentrations of pyrimethanil (0.06-0.5 or 1.0 mg L-1) assessed at three temperatures (15°C, 20°C, 25°C) revealed that pyrimethanil caused concentration-dependent effects independent of temperature. Interestingly, the ecotoxicity of pyrimethanil was higher at lower temperature for the embryo hatching and F1 reproduction, but its ecotoxicity for the growth of juveniles and the F0 reproduction increased with increasing temperature. More specifically, it could have been observed that especially during the reproduction test high mortality rates occurred at the highest concentration of 1 mg L-1 at all temperatures. Due to high mortality rates no snails were available for the F1 at the highest concentrations (0.5 and 1.0 mg L-1). Compared to the F0, overall more egg masses were produced in the F1, being all fertile and no mortality occurred. For the F1-generation the strongest pyrimethanil effects were detected at 15°C. A comparison of effect concentrations between both generations showed that the F1 is more sensitive than the F0.
These results indicate that an exposure over more than one generation may give a better overview of the impact of xenobiotics. With the establishment of an embryo and reproduction test under different temperatures and various concentrations of pyrimethanil with P. acuta we could successfully show that molluscs can respond more sensitive than model organisms and that both, chemical and thermal stressor strongly influence the behaviour of the pulmonates. It can be concluded that the high susceptibility for the fungicide observed in gastropods clearly demonstrates the complexity of pesticide-temperature interactions and the challenge to draw conclusions for the ecotoxicological risk assessment of pesticides under the impact of global climate change.
Biochemical and functional analysis of the ubiquitin binding properties of the NF-κB regulator NEMO
(2012)
Posttranslationale Modifikationen regulieren wesentliche Eigenschaften von Proteinen, wie z. B. Lokalisation, Konformation, Aktivität, Stabilität und Interaktionsfähigkeit. Eine besondere Form der Proteinmodifikation ist die Ubiquitylierung, bei der das kleine Protein Ubiquitin mit seinem C-Terminus kovalent an ein Substratprotein gebunden wird.
Die am besten untersuchte Funktion der Ubiquitylierung ist die Markierung eines Substrates für den Abbau durch das Proteasom. In den letzten Jahren wurde jedoch entdeckt, dass Ubiquitylierung in vielen Bereichen der Zelle eine wichtige Rolle spielt. Dazu gehören der Transport von Vesikeln, die Reparatur von DNA-Schäden und zelluläre Signalübertragung. Ubiquitin kann verschieden-artige Ketten bilden, indem ein Ubiquitin an eines der sieben Lysine (K6, K11, K27, K29, K33, K48, K63) oder den N-Terminus eines anderen gebunden wird. Diese unterschiedlichen Kettentypen regulieren verschiedene Prozesse. Z. B. dienen K48-verknüpfte Ubiquitinketten als Signal für den proteasomalen Abbau, wohingegen über K63 verknüpfte Ketten hauptsächlich eine Rolle bei Signalübertragungen spielen.
Die meisten Funktionen die durch Ubiquitylierung reguliert werden, werden durch Ubiquitinrezeptoren vermittelt, die eine Ubiquitinbindedomäne (UBD) besitzen. Manche UBDs binden selektiv nur einen Ubiquitinkettentyp und sind somit in der Lage gezielt Prozesse regulieren zu können, indem sie nur durch diesen speziellen Kettentyp aktiviert werden.
Das Protein NEMO ist ein Ubiquitinrezeptor, dessen UBD UBAN selektiv bestimmte Ubiquitinketten bindet. NEMO spielt eine zentrale Rolle bei der Aktivierung der Transkriptionsfaktorfamilie NF-κB, indem es den IKK-Kinasekomplex reguliert. Dieser Kinasekomplex sorgt durch die Phosphorylierung des NF-κB-Inhibitors IκBα für dessen proteasomalen Abbau, wodurch schließlich NF-κB aktiviert wird. Die NF-κB-Aktivierung kann u. a. durch den TNF-Rezeptor (TNFR) induziert werden. Am aktivierten TNFR werden viele Proteine durch verschiedene Ubiquitinketten modifiziert. Bisher wurde angenommen, dass die spezifische Bindung von NEMO an K63-verknüpfte Ubiquitinketten ausschlaggebend für die Aktivierung von IKK ist. Jedoch spielen lineare Ubiquitinketten, die über den N-Terminus verknüpft sind, auch eine wichtige Rolle bei der Aktivierung von NF-κB und die UBAN von NEMO hat eine sehr hohe Affinität zu linearen Ubiquitinketten.
Um die genauen Vorgänge zu verstehen, die zur Aktivierung von NF-κB am TNFR führen, ist es nötig, zu analysieren, welche Proteine mit welchen Ubiquitinketten modifiziert werden und welche Ubiquitinrezeptoren daran binden.
In dieser Studie sollte detailliert untersucht werden, mit welchen Ubiquitin-ketten NEMO bevorzugt interagiert. Dazu wurden in vitro-Bindungsstudien mit bakteriell aufgereinigtem NEMO und verschiedenen Ubiquitinketten durchgeführt. Des Weiteren sollte geprüft werden, wie die Bindung von NEMO an bestimmte Ubiquitinketten die Aktivierung von NF-κB reguliert.
Dabei ergab sich, dass sowohl NEMO in voller Länge, als auch die UBAN, bevorzugt mit linearen Ubiquitinketten interagieren, wohingegen die Interaktion von NEMO mit anderen Ubiquitinketten relativ schwach ist. Ausgehend von einer Kristallstruktur eines Komplexes aus der NEMO-UBAN und linearem di-Ubiquitin, wurden NEMO-Mutanten generiert, die seletkiv die Bindung von NEMO an lineare Ubiquitinketten verhindern, während die schwache Bindung von NEMO an längere K63-verknüpfte Ketten erhalten blieb. Um die Relevanz der Interaktion von NEMO mit linearen Ubiquitinketten für die Aktivierung von NF κB zu überprüfen, wurden diese NEMO-Mutanten dann verwendet um Zellen die kein NEMO exprimieren zu rekonstituieren. Nach Stimulation dieser Zellen mit TNFα wurde NF-κB kaum aktiviert, womit gezeigt werden konnte, dass NEMO gezielt an lineare Ubiquitinketten binden muss, um NF-κB zu aktivieren. Zusätzlich zu seiner Rolle bei der Aktivierung von NF-κB ist NEMO ein wichtiger Inhibitor der durch den TNFR induzierten Apoptose. In dieser Studie wurde gezeigt, dass diese Apoptoseinhibierung abhängig von der Bindung von NEMO an lineare Ubiquitinketten ist, da die Zellen die NEMO-Mutanten exprimierten, die keine linearen Ketten binden können, durch Apoptose starben, währen Wildtyp-Zellen überlebten.
Zusammenfassend konnte in dieser Studie gezeigt werden, dass NEMO bevorzugt und mit vergleichsweise hoher Affinität an lineare Ubiquitinketten bindet und dass diese spezifische Bindung wichtig für die Inhibierung von TNFR-induzierter Apoptose sowie für die Aktivierung von NF-κB ist.
The universal biological energy currency adenosine triphosphate (ATP) is synthesized by the F1Fo-ATP synthase in most living organisms. The overall structure and function of F-type ATPases is conserved in the different organisms. The F1Fo-ATP synthase consist of two domains; the soluble F1 complex has the subunit stoichiometry α3β3γδε and the membrane embedded Fo complex consists of subunits ab2c10-15 in its simplest form found in bacteria. F1 and Fo both function as reversible rotary motors that are connected by a central stalk (γε) and a peripheral stalk (b2δ).
For ATP synthesis, the electrochemical energy formed by a proton or sodium ion gradient is required. The ion translocation across the Fo subcomplex induces torque in the motor part of the enzyme (cnγε), which causes conformational changes in the α3β3 domain leading to ATP synthesis from ADP and inorganic phosphate (Pi) catalyzed in the β-subunits. ATP hydrolysis causes a reverse torque in the Fo subcomplex triggering uphill ion translocation from cytoplasm to periplasm, and the enzyme functions as an ion pump.
The ATP synthesis mechanism is well understood, since several high-resolution structures of F1 are available. In contrast, the ion translocation mechanism across the membrane, mediated by the Fo subcomplex, is not understood in its structural detail.
Subunit a and the c-ring form an ion pathway, but subunit b is needed to form an active ion translocation pathway in both H+- and Na+-dependent systems. Several high-resolution structures of c-rings have provided insights in the ion translocation mechanism. The different ion translocation models based on biochemical, biophysical and structural analysis are in agreement in the fact that ions are translocated through a periplasmic ion access pathway in subunit a to the middle of the membrane and there to the binding site of a c-subunit. After almost a whole rotation of the c-ring the ion returns into the a-c interface, where it can be released to the cytoplasm. In the different models the cytoplasmic access pathway has been proposed to be located in subunit a, at the a-c interface or within the c-ring. The driving force of torque generation has been proposed to be the pH gradient or membrane potential. Several biochemical studies show that a conserved arginine in helix four of subunit a (R226 in Ilyobacter tartaricus or R210 in Escherichia coli)plays a critical role in the ion translocation. The arginine has been proposed to function as an electrostatic separator between the cytoplasmic and periplasmic pathways and as a mediator of the ion exchange into the c-ring ion-binding site.
Structural data of a related enzyme (V1Vo-ATPase from Thermus thermophilus) has provided insight into the helical arrangement of the ion translocating subunits I and Lring (related to subunit a and the c-ring). These structures indicated a small interface between subunit I and the L-ring, and two four-helix bundles in the N-terminal domain of subunit I were proposed to build the periplasmic and cytoplasmic ion pathways. To comprehend the ion-translocation and torque generation mechanism in F1Fo-ATP synthase, structural data of an intact a-c complex is needed.
The goal of this work was to obtain structural data of subunit a, most preferably in a complex with the c-ring or additionally with subunit b. Therefore, a new purification procedure for the I. tartaricus Fo-subcomplex, heterologously expressed in E. coli cells, was established. The purified Fo was characterized biochemically and by Laserinduced liquid bead ion desorption mass spectrometry (LILBID-MS). These analyses showed that pure and completely assembled Fo containing all its subunits in the correct stoichiometry (ab2c11) was obtained. The purified Fo complex was stable at 4°C for several months and at room temperature in the presence of lipids for several weeks. A lipid analysis was performed by thin-layer chromatography (TLC) to investigate the qualitative lipid composition of I. tartaricus whole lipid extract and various I. tartaricus F1Fo isolates. The whole lipid extract contained PC, PG and PE lipids and probably cardiolipin. PC, PG and PE lipids were bound to wild type I. tartaricus F1Fo, whereas recombinant I. tartaricus F1Fo did not have any bound lipids, but was able to bind the synthetic lipids POPC and POPG if they were provided during the purification.
For subsequent structural studies the purified Fo was subjected to two-dimensional (2D) crystallization trials. Vesicles and sheets tightly packed with protein and crystals with a rare plane group for I. tartaricus c11 (p121) were obtained. The c-ring was visible in the CCD images, and immunogold-labeling revealed the presence of the His-tagged a-subunit in the reconstituted vesicles. Furthermore, atomic force microscopy (AFM) imaging showed protein densities next to the c-rings, which protruded less from the membrane (0.4±0.1 nm) than the c-ring (0.7±0.1 nm). These protein densities presumably belonged to subunit a.
Cryo-electronmicroscopy (cryo-EM) was used to collect data of the p121 crystals and a merged projection density map was calculated to 7.0 Å resolution. The unit cell of the crystals (81 × 252 Å) contained two asymmetric units with three c-rings in each and next to the c11-rings new prominent densities were visible. In each extra density up to 7 transmembrane helices were visible, belonging to the stator subunit a and/or subunit b. To elucidate whether there are conserved elements in the three extra densities non-crystallographic averaging was applied using a single-particle approach.
Six possible arrangements for the c-rings and the extra densities were identified and used for the averaging. The extra densities were enhanced only in one of the possible arrangements. The average showed a four-helix bundle and a fifth helix in close proximity to the c-ring. Two more helices were present in each position but their position was ambivalent. The data obtained in this work provides the first insight in the helical arrangement in the a-c interface of F1Fo-ATP synthase.
Im Rahmen dieser Arbeit konnte die Bindeeigenschaft des synaptischen Vesikelproteins SV31 zu den divalenten Metallionen Zn2+, Ni2+ sowie Cu2+ nachgewiesen und reproduziert werden. Die Bindung an Zn2+ wurde dabei sowohl in vitro an der Sepharosesäule als auch in vivo in NGF-differenzierten PC12-Zellen bestätigt (3.2.1 - 3.2.3). In einer Kollaboration mit dem Max-Planck-Institut für Biophysik wurde des Weiteren eine mögliche Zinktransportfunktion von SV31 untersucht. Dafür wurde die Ladungstranslokation durch myc-SV31-enthaltene CHO-Zellmembranen nach Zinkzugabe gemessen (3.2.5). Weiterhin konnte durch subzelluläre Fraktionierung von PC12-Zellen ein Verteilungsmuster des neuen Proteins in Mikrosomen unterschiedlicher Dichte dokumentiert werden. Durch die andauernde Expression von SV31-RFP in stabil transfizierten PC12-Zellen kommt es außerdem zur Beeinflussung des Expressionsmusters zahlreicher Markerproteine und damit einhergehend zu einer Dichteverschiebung somatischer Organellen (3.3.1 - 3.3.3). Kolokalisationsstudien von SV31 mit Markerproteinen zahlreicher Zellorganellen ergaben partielle Fluoreszenzüberlagerungen mit synaptischen Vesikelproteinen sowie eine Anreicherung von SV31 in Nähe der Plasmamembran. In diesem Zusammenhang zeigt sich ebenfalls eine Übereinstimmung der Lokalisation von SV31 mit den SNAREProteinen SNAP25 und Syntaxin1A (3.4.1 - 3.4.3). Die Ergebnisse der vorliegenden Arbeit erweitern nicht nur das Wissen um die funktionellen Eigenschaften von SV31, sie geben auch Anlass zum Nachdenken über mögliche Interaktionspartner des neuen Vesikelproteins. Die Fähigkeit zur Zinkbindung und -akkumulation auf präsynaptischer Seite rückt SV31, im Hinblick auf neurodegenerative Erkrankungen wie Alzheimer und Parkinson, auch in einen medizinisch relevanten Kontext. Durch Deduktion der hier aufgezeigten Ergebnisse entsteht ein erweitertes Verständnis der Relevanz von SV31 als funktionelle, zinkbindende Einheit im Rahmen der synaptischen Transmission.
BMPs control postnatal dendrite growth and complexity in sympathetic neurons / von Afsaneh Majdazari
(2012)
The vertebrate nervous system is a complex network of billions of neurons connected by dendrites and axons, integrated to functional circuits and areas/organs in the central and peripheral nervous system. The cells of the nervous system origin from common progenitors, which take on different cell fates based on intrinsic and extrinsic factors. These factors determine general neuronal traits, but also the morphology and the type of connections made to other cells. Mechanisms underlying axonal and dendritic growth are well described in contrast to the initiation of neurite growth, which remains to be fully elucidated, especially concerning dendrite formation. Recently BMPs have been identified as candidate dendrite inducing factors in sympathetic, cortical and hippocampal neurons. Here we focus on the in vivo role of BMPs on dendrite growth in sympathetic neurons as their development and differentiation processes have been analyzed in detail.
The importance of RNA in molecular and cell biology has long been underestimated. Besides transmitting genetic information, studies of recent years have revealed crucial tasks of RNA especially in gene regulation. Riboswitches are natural RNA-based genetic switches and known only for ten years. They directly sense small-molecule metabolites and regulate in response the expression of the corresponding metabolic genes. Within recent years, artificial riboswitches have been developed that operate according to user-defined demands. Hence, they represent powerful tools for synthetic biology.
This study focused on the development of engineered catalytic riboswitches for conditional gene expression in eukaryotes. A self-cleaving hammerhead ribozyme was linked to a tetracycline binding aptamer in order to regulate ribozyme cleavage allosterically with tetracycline. By integrating such a hybrid molecule into a gene of interest, mRNA cleavage and thereby gene expression is controllable in a ligand dependent manner. The linking domain between ribozyme and aptamer was randomised. Tetracycline inducible ribozymes were isolated after eleven cycles of in vitro selection (SELEX). 80% of the analysed ribozymes show cleavage that strongly depends on tetracycline. In the presence of 1 μM tetracycline, their cleavage rates are comparable to that of the parental hammerhead ribozyme. In the absence of tetracycline, cleavage rates are inhibited up to 333-fold. The allosteric ribozymes bind tetracycline with similar affinity and specificity as the parental aptamer. Ribozyme cleavage is fully induced within minutes after addition of tetracycline. Interestingly, the isolated linker domains exhibit structural consensus motives rather than consensus sequences.
When transferred to yeast, three switches reduced reporter gene expression by 30 - 60% in the presence of tetracycline; none of them controlled gene expression in mammalian cells. In vitro selected molecules do not necessarily retain their characteristics when applied in a cellular context. Therefore, high throughput screening and selection systems have been developed in mammalian cells. The screening system is based on two fluorescent reporter proteins (GFP and mCherry). 1152 individual constructs of the selected ribozyme pool were tested, but none of them reduced reporter gene expression significantly in the presence of tetracycline. The selection system employs a fusion peptide encoding two selection markers (Hygromycin B phosphotransferase and HSV thymidine kinase) facilitating both negative and positive selection. 6.5 x 104 individual constructs of the selected ribozyme pool are currently under investigation.
Das Burkitt Lymphom ist ein aggressives B-Zelllymphom, das in tropischen Regionen Afrikas und in Neu Guinea endemisch auftritt und vor allem bei Kindern vorkommt. Die sporadische Form des Burkitt Lymphoms tritt weltweit in geringerer Häufigkeit auf und betrifft alle Altersschichten. In nahezu allen endemischen Fällen ist das Epstein-Barr Virus in den Tumorzellen nachweisbar, jedoch nur in ca. 20 % der sporadischen Fälle. Der Beitrag von EBV zur Entstehung EBV-positiver Burkitt Lymphome ist seit über 50 Jahren EBV-Forschung ungeklärt. Im Jahr 2004 wurden im Genom des Epstein-Barr Virus eine Reihe von microRNAs entdeckt, die potentiell für die Pathogenese des EBV-positiven Burkitt Lymphoms relevant sein könnten. Da die Expression der viralen microRNAs seither für das Burkitt Lymphom nur unvollständig beschrieben worden sind, wurden sie in dieser Arbeit systematisch analysiert und dadurch ein vollständiges Expressionsprofil erstellt. Es konnte dabei keine Unterscheidung zwischen endemischen und sporadischen Fällen erreicht werden, jedoch wurden hierbei erstmals Fälle identifiziert, die trotz nachgewiesener EBV-Assoziation keine viralen microRNAs enthielten. Neben den viralen microRNAs könnten im Burkitt Lymphom auch die zellulären microRNAs für die Tumorentstehung von Bedeutung sein. Deshalb wurde in dieser Arbeit auch die Expression der zellulären microRNAs aus Burkitt Lymphom-Biopsien charakterisiert. Durch hierarchisches „Clustering“ bildeten sich drei Gruppen, die hauptsächlich durch An- und Abwesenheit von zwei microRNAs (miR21 und miR92a) definiert wurden, denen onkogenes Potential zugeschrieben wird. Die Expressionsmuster der einzelnen Gruppen weisen auf zelluläre Mechanismen der Pathogenese des Burkitt Lymphoms hin.
Die genetische Charakteristik des Burkitt Lymphoms ist eine Chromosomentranslokation, welche das Protoonkogen c MYC unter die Kontrolle von regulatorischen Elementen der Immunglobulingene bringt. Durch die somit erhöhte Transkription von c-MYC entfaltet das Genprodukt sein onkogenes Potential. Mutationen im offenen Leserahmen können dieses Potential zusätzlich verstärken. Da c MYC ein pleiotroper Transkriptionsfaktor ist und somit auf eine ganze Reihe zellulärer Prozesse Einfluss hat, bewirkt die Translokation massive Veränderungen in der Zelle. Vorangegangene Untersuchungen der Arbeitsgruppe zeigten, dass die antivirale Interferonantwort durch hohe c MYC-Expression unterdrückt wird. Diese Beobachtung liefert eine mögliche Erklärung für die Immunevasion von Burkitt Lymphom-Zellen, trotz Anwesenheit des EBV-Genoms. In Zelllinien, die aus Burkitt Lymphom-Biopsien generiert wurden, konnte gezeigt werden, dass EBV eine Interferoninduktion auslöst, die durch c-MYC unterdrückt wird. In dieser Arbeit konnte auch gezeigt werden, dass Epstein-Barr-virale Nukleinsäureprodukte durch den zytosolischen Rezeptor RIG-I Interferon induzieren, dieser aber durch die hohe c-MYC-Expression transkriptionell gehemmt wird. Neben RIG-I wurden weitere Rezeptoren und Mediatoren der Interferoninduktionskaskade identifiziert, die ebenfalls transkriptionell von c-MYC unterdrückt werden. Diese Ergebnisse stützen die Hypothese, dass c-MYC durch Unterdrückung der angeborenen Immunität die Immunevasion von Burkitt Lymphom-Zellen ermöglicht.