Biologische Hochschulschriften (Goethe-Universität)
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Rhythmic changes in environmental lighting conditions have ever been the most reliable environmental cue for life on earth. Nature has therefore selected a genetically encrypted endogenous clock very early in evolution, as it provided cells and subsequently organisms with the ability to anticipate persevering periods of light and darkness. Rhythm generation within the mammalian circadian system is achieved by clock genes and their protein products. The mammalian endogenous master clock, which synchronizes the body to environmental time, is located in the suprachiasmatic nucleus (SCN) of the hypothalamus. As an integral part of the time-coding system, the pineal gland serves the need to tune the body to the temporal environment by the rhythmic nocturnal synthesis and immediate release of the hormone melatonin. In contrast to the transcriptional regulation of melatonin synthesis in rodents, a post-translational shaping is indicated in the human pineal gland. Another important mediator of circadian time and seasonality to the body is the pituitary gland. The aim of this work was to elucidate regulation of melatonin synthesis in the human pineal gland. Furthermore, presence and regulation of clock genes in the human pineal and pituitary gland, and in the SCN were analyzed. Therefore, human tissue, taken from regular autopsies, was analyzed simultaneously for different parameters involved in melatonin biosynthesis and circadian rhythm generation. Presented data demonstrate that post-mortem brain tissue can be used to detect the remnant profile of pre-mortem adaptive changes in neuronal activity. In particular, our results give strong experimental support for the idea that transcriptional mechanisms are not dominant for the generation of rhythmic melatonin synthesis in the human pineal gland. Together with data obtained for clock genes and their protein products in the pituitary, data presented here offer 1) a new working hypothesis for post-translational regulation of melatonin biosynthesis in the human pineal gland, and 2) a novel twist in the molecular competence of clock gene proteins, achieved by nucleo-cytoplasmic shuttling in neuronal and neuroendocrine human tissue. Furthermore, in this study, oscillations in abundance of clock gene proteins were demonstrated for the first time in the human SCN.
Compared to all other organisms with 1 to 3 heat stress transcription factors (Hsfs) or Hsf-related factors, plants have extraordinarily large Hsf families with more than 20 Hsfs. Plant Hsfs are classified into three classes according to their oligomerization domains which is built of hydrophobic heptad repeats (HR) in two parts, HR-A and HR-B. Both parts may be immediately adjacent (class B), or they are separated by insertion of 21 (class A) and 7 amino acid residues (class C). In plant Hsf family, detailed investigations are so far limited to Hsfs A1a, A2, A3, A4d, A9, and B1. They strongly indicate functional diversification to be the main reason for the coexistence of multiple Hsfs. As an example the functional triad of HsfA1a, HsfA2, and HsfB1 is essential for all three phases of the hs response, (i) the triggering of the response by HsfA1a as master regulator, (ii) the maintenance and high efficiency of hs gene transcription by cooperation of HsfA1a with Hsfs A2 and B1, and finally, (iii) the restoration of house-keeping gene transcription during the recovery phase mediated by HsfB1 in cooperation with house-keeping transcription factors. The results presented in this thesis for Hsfs A4 and A5 open completely different aspects of functional diversification and cooperation of Hsfs. HsfA4 and HsfA5 homooligomerize and bind to corresponding HSE motifs. But in contrast to the highly active HsfA4, HsfA5 is completely inactive as transcriptional activator. Yeast two hybrid and GST pull-down techniques showed that both Hsfs have strong tendency for heterooligomerization. Using fluorescence microscopy the HsfA4/A5 heterooligomers were found to localize in the nucleus. These complexes are transcriptionally inactive due to the impairment of DNA binding. The repressor function of HsfA5 requires only its OD and no additional factors, e.g. a putative co-repressor recruited by the C-terminal domain, are involved. Evidently, the repressor effect mainly results from the interference with the oligomeric state of HsfA4b, which is essential for efficient DNA binding and activator functions. EST database search revealed that plants have a single HsfA5 and usually two A4-type Hsfs. Using bioinformatics tools, Hsfs A4 and A5 were found to be phylogenetically closely related and clearly distinct from the other members of the Hsf family. On the basis of RT-PCR and Microarray data the representatives of the A4/A5 group are well expressed in different plant tissues albeit at very different levels which change with the developmental stages and stress conditions In rice and Arabidopsis, HsfA4 functions as an anti-apoptotic factor for stress induced oxidative damages. Based on my results, I hypothesize that HsfA5 functions as a novel type of selective repressor, regulating the function of A4-type Hsfs in plants. Considering the high sequence conservation with in plant Hsf family, it is tempting to speculate that this role of Hsf4/A5 pair is a fundamental feature of the Hsf system in plants.
Synaptopodin is the founding member of a family of actin-associated proline-rich proteins. It is present in a subset of telencephalic dendritic spines, where it is tightly associated with the dendritic spine apparatus, a putative calcium store. Synaptopodin-deficient mice lack the spine apparatus and show deficits in long-term potentiation and spatial memory. Thus, synaptopodin appears to play a role in synaptic plasticity. In the present thesis, three major questions were addressed: (1) What is the distribution of synaptopodin and the spine apparatus in identified hippocampal neurons? (2) Is the distribution of synaptopodin affected by denervation? (3) Is synaptopodin involved in the regulation of denervation-induced spine loss? The major findings of this thesis are: (1) Immunohistochemistry in the hippocampus of wildtype and EGFP-transgenic mice revealed significant layer-specific differences in the prevalence of synaptopodin at the level of individual neurons. (2) Light and electron microscopic analysis also revealed the presence of synaptopodin in axon initial segments of cortical and hippocampal principal neurons. There, it was found to be an essential component of the cisternal organelle, a putative axonal homologue of the dendritic spine apparatus. (3) Immunohistochemistry in the rat fascia dentata before and following entorhinal deafferentation revealed changes in synaptopodin expression in denervated and non-denervated layers of the hippocampus, suggesting that the distribution of synaptopodin in hippocampal neurons is regulated by presynaptic signals. (4) The dynamics of denervation-induced spine plasticity were studied in vitro using confocal live imaging of organotypic entorhino-hippocampal slice cultures. Whereas spines were remarkably stable under control conditions, spine loss and spine formation were seen following denervation. No significant differences were observed between cultures from wildtype and synaptopodin-deficient mice, suggesting that synaptopodin is not involved in lesion-induced spine plasticity. (5) Finally, a set of transgenic mice expressing fluorescently tagged synaptopodin were generated to facilitate future experiments on the dynamics and function of synaptopodin. In summary, this thesis presents novel findings on (1) the subcellular distribution of synaptopodin in spines and the axon initial segment, (2) the molecular composition of the cisternal organelle, and (3) the dynamics of spines and the spine apparatus organelle following deafferentation in vivo and in vitro.
Koalas are popular zoo animals, but difficult in husbandry. In addition to their specialised diet of eucalyptus leaves, they are prone to “stress” and disease. Particularly in European zoos, themonitoring of theirwell-being has high priority and they are protected from possible stressors. However, stress signs in koalas are vague and monitoring techniques like weighing might result in discomfort itself. Additionally, husbandry routines are planned according to keeper’s schedule, not to the endogenous rhythms of the koalas. Therefore it is necessary to investigate activity pattern in captive koalas and the signals influencing them. These signals have to be assessed on the strength and quality of their impact. A total of 17 koalas have been observed in three zoological gardens in Australia and Europe. Koalas kept in outdoor enclosures with little human contact (Koala Walkabout, Taronga Zoo, Sydney) showed a uniform activity pattern, which was clearly entrained by light. Activity levels were higher during the night, and there was a pronounced resting period in the morning which corresponds with low body temperature measured by Degabriele and Dawson (1979). Activity peaks were related to twilight and changed during the year related to day lengths. However, there was a clear influence from the introduction of fresh browse which resulted in a distinct feeding peak in the afternoon. With short day lengths, this stimulus competed with dusk. Activity patterns from koalas in indoor enclosures (Zoo Duisburg, Vienna Zoo) varied between individuals and in some cases lacked a detectable rhythm. Though activity peaks were related to light, entrainment to sunlight was weak. In winter, koalas reacted primarily to the artificial light, but some also showed activity peaks related to sunlight. Activity patterns in these koalas were less structured and differed severely from patterns expected according to literature. Activity was often related to the keeper’s presence and food introduction. Frequency of feeding bouts was considerably higher at Vienna Zoo compared to the other zoos and the bouts were shorter in duration. Time budgets of the koalas were within the range given in free-range studies. Feeding showed seasonal changes and was increased in lactating females. Koalas at Vinna Zoo had a high level of locomotor activity compared to the size of the enclosure. Koalas at Koala Walkabout were not used to handling, so they resisted the keeper. The koalas at the two European zoos were handled regularly and settled down quickly. However, handling took place in the morning; in most koalas, there was no activity prior to it. In Vienna, resting periods were interrupted daily due to weighing. Food introduction at KoalaWalkabout took place in the afternoon. It was preceded by locomotor activity and triggered a long feeding bout in the koalas. It is not clear, whether food had true Zeitgeber properties or masked the endogenous rhythm. In the two European zoos, food was introduced in the morning. The peaks related to this were smaller than those at Koala Walkabout. Activity was rarely observed prior to food introduction. The koalas at Koala Encounter, Taronga Zoo (Sydney),were regularly confronted with visitors, though no contact was allowed. Direct observation by the keepers did rarely show any stress signs. Activity patterns at night were strikingly similar to Koala Walkabout, but differed dramatically during the day. Food was introduced three times a day, which usually resulted in activity that interrupted a resting period. Generally, the koalas at Koala Encounter were more active than those at KoalaWalkabout. They also displayed a high level of locomotor activity, especially on the ground, which is an accepted sign of discomfort in koalas (Wood 1978; Zoological Society of San Diego 2001; Yusuf& Rosenthal unpublished data). In summary, this chronoethological study of the captive koalas showed that there are several problems with koala husbandry. Artificial light regimes for koalas are not sufficient for entrainment and result in unstructured activity pattern. This is especially the case in winter, when the day in Europe is artificially extended. Due to the mainly nocturnal behaviour of koalas, such an extension might not be necessary and therefore should be avoided. Handling in Europe took place during the physiological resting time of the koalas. Interruptions of resting times are considered as stressors (Wood 1978) and should be avoided. Handling in the afternoon would be more suitable for the koalas and triggered activity in the two koalas at Vienna Zoo. It is also arguable if daily weighing is necessary to monitor health in captive koalas or if the frequent interruption of resting countervail the advantages of constant monitoring. Frequent contact with visitors, evenwithout the so-called cuddling, has a considerable impact on activity patterns and time budget of koalas, even if no immediate stress signs are displayed. Such contact should therefore be reduced to a minimum and chronoethological observations of the koalas should be used. A study on koalas with direct visitor contact is also advisable to revise the current legislation on “koala cuddling”. Koalas frequently rested in living trees if they had access to it. Since no food-poisoning has been reported from koalas using living non-food trees, the provision of living trees with an appropriate canopy should be included in the husbandry guidelines. Increased locomotor activity has been shown to be related to conditions of discomfort or stress and possibly to oestrus. This is in accordance with literature (Wood 1978; Zoological Society of San Diego 2001). Further observation, combined with hormone analysis, are advisable to establish this parameter for evaluation of well-being. Chronoethology has proven to be useful for the evaluation of husbandry conditions and group dynamics. Different to other, traditional ethologicalmethods, it indicated problems and enabled me to advise more appropriate times for handling and food introduction. It is desirable that zoos already using 24-hour video observation include chronoethological aspects into their analysis.
Spatio-temporal dynamics of primary lymphoid follicles during organogenesis and lymphneogenesis
(2007)
Primary lymphoid follicles are structures which are important for adaptive immune responses in mammals. Within the follicles follicular dendritic cells (FDC) are maintained by constant stimuli provided by B cells. It is thought that the FDC are important for immune response. It is of interest to know how lymphoid follicles are regulated in order to understand their role in various autoimmune diseases in which these follicles are created ectopically. With the help of a tissue simulation relying on an agent-based cell model on top of a regular triangulation various scenarios suggested by the available experimental data have been investigated. In order to cope with the complexity in the simulation of immune tissue the regular triangulation has been implemented for the use on parallel computers. The algorithms for kinetic and dynamic regular triangulation have been created newly. Also the cell model underlying the simulation has been designed newly in many aspects. The simulations allowed to identify common factors that regulate the formation of lymphoid follicles normally during organogenesis in development and lymphneogenesis in the course of diseases. The generation of FDC from local stromal populations under the influence of B cell aggregates is shown to be possible with the given experimental parameters. The sequence of the organogenesis and lymphneogenesis can be described with regard to the morphology of the B and T zone. Tests for the stability of the primary lymphoid follicle system constraints the regulation of the B cell efflux. The required lymphatic vessels around the lymphoid follicle are shown to be negatively correlated with the FDC network. Moreover it is shown that the adjacent T zone consisting of its own stromal population and T cells has similar regulation principles. This easily explains the intermediate ring of B cells found around the T zone during development and certain signaling molecule deficiencies. A major result of this thesis is that the generation of FDC needs negative regulation while a number of other possible mechanisms is incompatible with the available experimental data. Moreover the observed microanatomy was brought into a functional relationship with data on the cellular level finally culminating in the proposal of new experiments that shed light on the dynamics of the primary lymphoid follicle. One conclusion is that the FDC directly or indirectly influence the angiogenesis and lymphangiogenesis processes in secondary lymphoid tissues. The work presented here may help to guide experiments with the help of computers in order to reduce the amount of experiments and design them in a way to maximize the amount of information about biological systems.
Purification and characterization of heterologously produced cannabinoid receptor 1 and G proteins
(2007)
G protein coupled receptors form the largest group of transmembrane proteins, which are involved in signal transduction and are targeted directly or indirectly by 40-50% of the drugs in the market. Even though a lot of biochemical and pharmacological information was acquired for these receptors in the past decades, structural information is still insufficient. G protein coupled receptors are expressed in a very minute scale in the tissues. Purification of G protein coupled receptors, in amounts needed for structural studies, from native tissue is tedious and almost impossible. To overcome this first hurdle of insufficient protein, several heterologous protein expression systems are being used. Another difficulty in structural determination of a G protein coupled receptor is that it is a membrane protein. Membrane proteins are difficult targets for structural studies. One of the possible reasons is the little hydrophilic surface area on the membrane protein, reducing the chances of crystal contact between the molecules. The present work is an attempt to investigate possible ways to overcome these problems. Aim of the project was to use G proteins to increase the hydrophilic area of the G protein coupled receptor. G protein is a physiological partner to the G protein coupled receptor which makes the complex functionally relevant. In the present work five G alpha proteins were purified to homogeneity by a two step purification using metal affinity and ion-exchange chromatography. The G alpha subunits purified were tested for their detergent susceptibility. It was found that only some G proteins were active in the presence of detergent. Observation from contemporary reports also suggest that the G alpha proteins expressed in Escherichia coli, alone may not be sufficient to bind to the G protein coupled receptors in solution. So the project was extended towards expressing a G protein coupled receptor which was reported to exist in a complex with the G proteins, in the cells. Purifying such a functional complex could be more beneficial to use for crystallization. Cannabinoid receptors were chosen for heterologous expression and purification. Production of recombinant cannabinoid receptor 2 was investigated in Pichia pastoris. The protein obtained was highly heterogenous. There were several oligomeric forms as well as degradation products in the cell membranes. Most of the protein was lost in the purification steps leading to a poor yield. Several oligomeric forms and other impurities were still present in the protein sample after purification. Alternatively, a baculovirus mediated insect cell expression system was investigated, to produce the receptors. Cannabinoid receptor 1 was investigated in insect cell expression system because of its better biochemical understanding and pharmacological importance than cannabinoid receptor 2. Cannabinoid receptor 1 was produced in two forms, a full length and a distal carboxy terminal truncated version. All the several gene constructs made could be expressed in the Spodoptera frugiperda (Sf9) insect cells. Expression levels (Bmax) for the constructs with a decahistidine tag at the amino terminus and Strep-tagII at the carboxy terminus were 40 pmol/mg and 53 pmol/mg respectively, for full length and truncated versions. These expression levels are 2 fold higher than the levels reported till now in the literature. As was quite evident from previous experiences of other research groups, purification of this receptor was a challenge. Protein purified from immobilized metal affinity chromatography (Ni-nitrilo tri acetate)(Ni-NTA) was not even 50% pure. A second purification by immobilized monomeric avidin or Streptactin agarose, making use of Biotag and StreptagII respectively, drastically reduced the protein recovery. Later on, purification of receptor was investigated on different metal chelating resins. His-Select, a Ni-NTA based matrix from Sigma, with much lesser density than Ni-NTA from Qiagen, showed a better purification profile. Purification was optimized to get 80% homogeneity but with low yield (20%). Further efforts are needed to improve the yield and purity of the receptor, to use it for crystallization. Cannabinoid receptors are known to exist in a precoupled form to G proteins in the cells. The existence of such precoupled forms of the receptor was investigated using the fluorescence techniques. Guanosine-5-triphosphate binding assay on the cell membranes, in the absence of agonists confirmed the active precoupled form of the receptor. It was found that it is possible to co-immunoprecipitate the complex. These results show that the truncated cannabinoid receptor can be produced in functional form in insect cells in much higher yields than reported. This receptor exists as a complex with G proteins even in the absence of ligands. It was also shown that the receptor/G protein complex can be coimmunoprecipitated. Further work is required to investigate the possibility of purifying this complex to use it for co-crystallization.
Two types of proteins transport ions across the membrane – ion channels and ion pumps. Ion pumps transport ions against their electrochemical gradient by co-transporting another ion or a substrate molecule through a concentration gradient or by coupling this process to an energy source like ATP. Those that couple ATP hydrolysis to ion transport are called ion motive ATPases and can be classified as ‘V’, ‘F’ and ‘P’ types. In this thesis, two sub-classes of P-type ATPases, PIIIA and PIB were studied. Attempts were made to over-express and crystallize the plant proton pump AHA2 (a PIIIA-ATPase). Also, the two putative copper transporting ATPases, CtrA3 (CopB-like) and CtrA2 (CopA-like) from Aquifex aeolicus (both PIB pumps) were over-expressed in E. coli and characterized. PIIIA-type pumps transport protons across the membrane and are found exclusively in plants and fungi, and probably some archaea. One of the most characterized proton pump biochemically is the A. thaliana proton pump AHA2. An 8Å projection map of this enzyme is already available (Jahn 2001). PIBATPases, also called CPX type pumps transport heavy metal ions such as Cu+, Cu2+, Zn2+, Pb2+, Cd2+, Co2+ across biological membranes and play an important role in homeostasis and biotolerance of these metals. CopA and CopB are two such proteins that transport copper across cell membrane found in many prokaryotes. CopB-like proteins are found almost exclusively in bacteria, with CPH sequence motif, while CopA-like proteins have CPC sequence motif, also found in eukaryotic copper transporters including human ATP7A and ATP7B. CopB extrudes Cu2+ across the membrane. CopA is activated by and transports Cu+ but the direction of transport is debated. Attempts were made to over-express the plant proton pump AHA2 in yeast Pichia pastoris. However, the yeast expressed only a truncated protein, which could not be used for further studies. It can be concluded that P. pastoris strain SMD1163 is not a good host for expression of AHA2. Focus was then shifted to AHA2 that has been over-expressed and purified from S. cerevisiae strain RS72. Growth and purification protocols had to be changed from published methods because of laboratory constraints and this probably had an effect on the protein produced. The protein purified from S. cerevisiae could not be crystallized reproducibly for structural studies by electron microscopy. CtrA3 was expressed in E. coli and purified using Ni2+-NTA matrix. Like CopB of A. fulgidus (Mana Capelli 2003), it was active only in the presence of Cu2+ and to some extent in Ag+. The protein was maximally active at 75°C, at pH 7 and in presence of cysteine. Lipids were essential for the activity of CtrA3. However, when the protein was purified in Cymal-6, CtrA3 could not hydrolyze ATP, even when lipids were added to the reaction mixture. For reconstitution of CtrA3 into liposomes for 2D crystallization, several lipids were tested. To screen the lipids compatible for protein incorporation, CtrA3 was dialyzed with different lipids at a high lipid-to-protein ratio of 10:1 and centrifuged by sucrose density gradient. Protein incorporated in lipids localized with liposome fraction in the gradient. Most of the CtrA3 was incorporated into DPPC with no aggregation. This lipid was used for reconstitution of CtrA3 at low LPRs, and at an LPR of 0.3-0.5, the protein formed 2D crystals. A NaCl concentration of 50mM was necessary for the formation of crystals. However, salt removal by dialysis prior to harvesting was essential for obtaining wellordered lattices of CtrA3. Addition of preservatives like trehalose and tannin or direct plunging in liquid ethane for cryo-microscopy destroyed the crystal lattice. Similar to CtrA3, the gene responsible for expression of CtrA2 was amplified from genomic DNA of A. aeolicus and expressed in E. coli and purified by Ni2+-NTA. Functional characterization of CtrA2 was done by analyzing ATP hydrolysis activity of the enzyme. Similar to CopA of A. fulgidus (Mandal 2002), CtrA2 was activated in the presence of Ag+ and to some extent, Cu+. It is possible that both the copper ATPases of A. aeolicus have different ion selectivity- CtrA3, specific for Cu2+ and CtrA2, specific for Cu+. Maximal activity of CtrA2 was also at 75°C. Cysteine was essential for activity of CtrA2, but the protein was not dependent on addition of lipids for activation. Reconstitution of CtrA2 was done similar to CtrA3 for screening of lipids for 2D crystallization. Of the lipids tested, DOPC reconstituted the protein best. However, screening at low LPRs did not yield any crystals. Even though both CtrA3 and CtrA2 are similar heavy metal transporting Ptype ATPases from the same organism and have 36% identity, they behaved completely different in their expression levels in E. coli, purification profiles, activity and reconstitution in lipids.
The following thesis is concerned with the elucidation of structural changes of RNA molecules during the time course of dynamic processes that are commonly denoted as folding reactions. In contrast to the field of protein folding, the concept of RNA folding comprises not only folding reactions itself but also refolding- or conformational switching- and assembly processes (see chapter III). The method in this thesis to monitor these diverse processes is high resolution liquid-state NMR spectroscopy. To understand the reactions is of considerable interest, because most biological active RNA molecules function by changing their conformation. This can be either an intrinsic property of their respective sequence or may happen in response to a cellular signal such as small molecular ligand binding (like in the aptamer and riboswitch case), protein or metal binding. The first part of the thesis (chapters II & III) provides a general overview over the field of RNA structure and RNA folding. The two chapters aim at introducing the reader into the current status of research in the field. Chapters II is structured such that primary structure is first described then secondary and tertiary structure elements of RNA structure. A special emphasis is given to bistable RNA systems that are functionally important and represent models to understand fundamental questions of RNA conformational switching. RNA folding in vitro as well as in vivo situations is discussed in Chapter III. The following chapters IV and V also belong to the introduction part and review critically the NMR methods that were used to understand the nature and the dynamics of the conformational/structural transitions in RNA. A general overview of NMR methods quantifying dynamics of biomolecules is provided in chapter IV. A detailed discussion of solvent exchange rates and time-resolved NMR, as the two major techniques used, follows. In the final chapter V of the first part the NMR parameters used in structure calculation and structure calculation itself are conferred. The second part of the thesis, which is the cumulative part, encompasses the conducted original work. Chapter VI reviews the general NMR techniques applied and explains their applicability in the field of RNA structural and biochemical studies in several model cases. Chapter VII describes the achievement of a complete resonance assignment of an RNA model molecule (14mer cUUCGg tetral-loop RNA) and introduces a new technique to assign quaternary carbon resonances of the nucleobases. Furthermore, it reports on a conformational analysis of the sugar backbone in this RNA hairpin molecule in conjunction with a parameterization of 1J scalar couplings. Achievements: • Establishment of two new NMR pulse-sequences facilitating the assignment of quaternary carbons in RNA nucleobases • First complete (99.5%) NMR resonance assignment of an RNA molecule (14mer) including 1H, 13C, 15N, 31P resonances • Description of RNA backbone conformation by a complete set of NMR parameters • Description of the backbone conformational dependence in RNA of new NMR parameters (1J scalar couplings) Chapters VII & VIII summarize the real-NMR studies that were conducted to elucidate the conformational switching events of several RNA systems. Chapter VIII gives an overview on the experiments that were accomplished on three different bistable RNAs. These molecules where chosen to be good model systems for RNA refolding reactions and so consequently served as reporters of conformational switching events of RNA secondary structure elements. Achievements: • First kinetic studies of RNA refolding reactions with atomic resolution by NMR • Application of [new] RT-NMR techniques either regarding the photolytic initiation of the reaction or regarding the readout of the reaction • Discovery of different RNA refolding mechanisms for different RNA molecules Deciphering of a general rule for RNA refolding methodology to conformational switching processes of RNA tertiary structure elements. The models for these processes were a) the guanine-dependent riboswitch RNA and b) the minimal hammerhead ribozyme. Achievements: • NMR spectroscopic assignment of imino-resonances of the hypoxanthine bound guanine-dependent riboswitch RNA • Application of RT-NMR techniques to monitor the ligand induced conformational switch of the aptamer domain of the guanine-dependent riboswitch RNA at atomic resolution • Translation of kinetic information into structural information • Deciphering a folding mechanism for the guanine riboswitch aptamer domain • Application of RT-NMR techniques to monitor the reaction of the catalytically active mHHR RNA at atomic resolution In the appendices the new NMR pulse-sequences and the experimental parameters are described, which are not explicitly treated in the respective manuscripts.
Seit gezeigt wurde, dass die genetischen Informationen in Form von DNA gespeichert wird, ist das Geheimnis der DNA-Struktur gelöst, der Mechanismus der Gen-Expression und die Rolle der RNA verstanden worden. Das Interesse für die Chemie und die Biologie der Nukleinsäuren ist somit kontinuierlich gewachsen. Besonders interessant ist die RNA, die eine Rolle als ein Vermittler der genetischen Informationen (mRNA) spielt, aber auch als Bote von Aminosäuren (tRNA). Sie ist im Ribosom (rRNA) anwesend, arbeitet als Templat in Telomerasen für DNA-Synthese und hat außerdem wichtige Funktionen in der RNA-Spaltung, z.B. bei Ribozymen wie RNAse P inne. Betreffend bestimmter Spaltstellen in RNA hat auch das Phänomen der siRNA beträchtliche Aufmerksamkeit in diesem Prozess erregt. Der sogenannte RISC-Komplex wird programmiert, einzelsträngige RNA mit hoher Sequenz-Spezifität zu schneiden. Die für die RNA-Interferenz verantwortliche zelluläre Maschinerie ist auch an der Bilbung von MikroRNAs beteiligt. RNA-Interferenz ist heute eines der nützlichsten Werkzeuge in functional genomics geworden. Die große Hoffnung ist, dass es auch vielleicht in der Therapie angewandt werden könnte. Das Thema meiner Doktorarbeit trägt den Titel „Synthesis of Site-Specific Artificial Ribonucleases“. Es beschäftigt sich mit der Entwicklung künstlicher bindungsspezifischer Ribonucleasen. Diese künstlichen Katalysatoren sind im Wesentlichen aus drei Gründen bedeutsam: Zum einen liegt eine mögliche Anwendung in der Affinity-Cleavage (Affinitätsspaltung), eine Technik, die Bindungsstellen von RNA-Liganden durch das kovalente Anbringen eines Reagenzes lokalisiert, das zwischen den Nukleinsäuren schneidet. Zum anderen entsteht die Möglichkeit, neue Werkzeuge für eine gezielte Manipulation großer RNA-Moleküle zu schaffen. Die Vorteile des Ansatzes sind, dass man damit beliebige Zielsequenzen anwählen kann. Das Problem dieser Strategie ist die Notwendigkeit, hohe Genauigkeit im Spaltungssschritt zu erreichen, wie zum Beispiel mit natürlichen Ribozymen. Wichtige Ergebnisse wurden auch während meiner Arbeit erhalten, mit einem Fall von genauer Spaltung zwischen zwei Basen. Der dritte Grund ist die potentielle Anwendung als katalytische antisense-Oligonucleotide in der Chemotherapie. Gegenwärtig existieren zwei Ansätze, unspezifische künstliche RNasen relativ kleiner Größe zu schaffen. Der erste basiert auf Metallkomplexen und führt im Allgemeinen zu höheren Raten. Die Idee ist, ein Metall als elektrophiles Zentrum zur Unterstützung der Transesterfikation zu nutzen. Unter diesen Katalysatoren enthalten die effizientesten Lanthanid-Ionen, Cu2+ und Zn2+. Der zweite Ansatz zielt darauf ab, metallfreie künstliche Ribonucleasen zu entwickeln. Die Vorteile dieser Strategie sind, den Katalysator von der Stabilität der Metallkomplexe, die in vivo problematisch sein könnten, unabhängig zu machen. In diesem Ansatz wird die natürliche Katalyse durch Enzyme simuliert. Zweckmäßige Gruppen mit beschränkter katalytischer Aktivität z.B. als Nucleophile, Säuren oder Basen, werden in einer Weise zusammengesetzt, um Kooperation zu ermöglichen. Potente Katalysatoren können so ohne die Notwendigkeit von Metallen als Cofaktoren erzeugt werden. ...
Leukemia inhibitory factor enhances neurogenin's pro-neural effect during mouse cortical development
(2007)
Die Entwicklung von unterschiedlichen Zelltypen waehrend der embryonalen ZNS-Entwicklung ist abhaengig von zellintrinsischen und positionsabhaengigen, aeusseren Einfluessen. Dabei bilden sich die verschiedenen Zellen in nacheinander ablaufenden bzw. sich teilweise ueberlappenden Zeitraeumen. Zuerst entstehen Radiaglia und Neuronen, nachfolgend Astrozyten und zuletzt Oligodendrozyten. Werden neurale Stammzellen/Vorlaeuferzellen (NPCs – neural precursor cells) zu unterschiedlichen Zeitpunkten entnommen und ohne den Einfluss von Wachstumsfaktoren kultiviert, so entwickeln sich diese Zellarten in der gleichen Reihenfolge. Die Neurogenese, die bei Mausembryos am Tag E11-12, nach dem Etablieren der Radialglia, beginnt, findet an E14 ihren Hoehepunkt. Zu diesem Zeitpunt werden die Gene Neurogenin1 (Ngn1) und Ngn2 in den neuralen Vorlaeuferzellen der Ventrikularzone des dorsalen Cortexes in hohem Masse exprimiert. Wie aus Untersuchungen von unserm Labor gezeigt wurde, beguenstigt es die Entstehung von Neuronen und blockiert gleichzeitig Pro-Astrozyten-Einfluesse. Zum einen inhibiert Ngn den JAK/STAT Signalweg, dessen Aktivierung fuer die Gliogenese noetig ist, indem es die Phosphoylierung von STAT1/3 auf bisher noch unbekannte Weise blockiert. Ausserdem bindet der Transkriptions-Coaktivator cAMP-response element binding protein (CBP), welches auch von den STATs fuer die Transkription benoetigt wird, bevorzugt an Ngn sobald dieses von den Vorlaeuferzellen exprimiert wird. Mit dem Tag E16 nimmt die Neurogenese in vivo wieder stark ab und es setzt die Gliogenese ein, bei der zunaechst ueberwiegend Astrozyten gebildet werden. Faktoren wie leukemia inhibitory factor (LIF) sowie ciliary neurotrophic factor (CNTF) beguenstigen dabei die Astrozytogenese indem sie den JAK/STAT Signalweg aktivieren. Die Bindung von LIF/CNTF fuehrt zur Phosphorylierung von STAT-Transkriptionsfaktoren, die ihrerseits dann an den CBP/p300 Komplex binden und schliesslich die Expression von Astrozyten-spezifischen Genen aktivieren. Die STAT-Faktoren koennen aber erst nach Abfall des Ngn-Spiegels an den Transkriptions-Coaktivator binden, da sich die Bindungsstellen dieser beiden ueberlappen. Um die Hypothese zu ueberpruefen, dass LIF auch die Neurogenese, oder spezifischer, die Wirkung von Ngn positiv beeinflusst, wurden cortikale NPCs von murinen Embryos entnommen und der Wirkung von LIF via Luciferase Assay untersucht. Dabei wurden die Vorlaeuferzellen mit Ngn und einem Reporter transfiziert, welcher den NeuroD-Promoter beinhaltete. NeuroD-Expression findet in der Regel gegen Mitte/Ende der Neurogenese statt und ist wichtig fuer die Reifung von Neuronen. Der Promoter von NeuroD beinhaltet ein E-box Element, an welches Ngn bindet und die Transkription einleitet. Wie unsere ersten Versuche zeigten, verstaerkt LIF die Transkriptionsaktivitaet von Ngn und somit die Transkription von NeuroD. Wenn aber im selben Versuch ein NeuroD-Reporter transfiziert wurde, dessen E-box mutiert war, wurde keine Transkriptionsaktivitaet gemessen, was wiederum bestaetigte, dass der pro-neurale LIF-Effekt ueber Ngn lief und E-box-Bindung noetig war. Um den Einfluss des pro-neuralen Effekts von LIF auf Proteinebene zu testen, wurden NPCs mit Ngn-Adenovirus infiziert und mit LIF stimuliert. Dabei wurden die Zellen auf die Expression von Neuron-spezifischem class III β-tubulin (TuJ1) untersucht. Die Ergebnisse zeigten, dass LIF bei Zellen, die Ngn exprimierten, die Rate der Neuronen von etwa 5% auf etwa 50% anstiegen liess, waehrend LIF bezueglich der Gliogenese (gezeigt durch die Expression von GFAP) in Ngn-exprimierenden Vorlaeuferzellen kaum Wirkung zeigte. Als naechstes sollte untersucht werden ueber welchen Signalweg LIF Ngn aktivierte. LIF bindet zunaechst an LIF receptor β (LIFRβ), der dann an glycoprotein 130 (gp130) bindet. Diese Bindung fuehrt dann zur Aktivierung mehrerer Signalkaskaden: dem JAK/STAT, dem MAPK, dem Akt/PI3K und dem PLCγ/PKC Signalweg. Da der JAK/STAT Signalweg fuer die Gliogenese wichtig ist, lag unser Fokus auf den anderen Signalwegen. Deren Aktivierung wurde dann mit spezifischen Inhibitoren blockiert und, wie auch in den Vorversuchen, die Wirkung von LIF auf Transkriptionsebene (NeuroD) in neuralen Vorlaeuferzellen bestimmt. Dabei zeigte sich, dass die Blockierung des PLCγ/PKC Signalweges die NeuroD-Promoteraktivitaet am starksten inhibierte, waehrend auch LIF´s pro-neurale Wirkung verloren ging. Dementsprechend zeigte die Western Blot Analyse, dass die Expression von class III β-tubulin (TuJ1) durch die Anwendung der PKC Inhibitoren am staerksten inhibiert wurde, wobei auch hier die Stimulation durch LIF keine erhoehte Neurogenese mit sich zog. In weiteren Versuchen konnten wir dann mit Hilfe von Immunoprezipitation demonstrieren, dass LIF die Bindung von Ngn an CBP verstaerkte (eine Bindung, welche durch PKC Inhibitoren aufgehoben wurde), was wiederum zu einer erhoehten Bindung dieses Transkriptionskomplexes an den NeuroD Promoter fuehrte, wie unsere Chromatin Immunoprezipitation (ChIP) Daten beweisen. Dies wiederum laesst darauf schliessen, dass womoeglich diese erhoehte Ngn-CBP/NeuroD-Promoter Bindung der Grund fuer die erhoehte NeuroD-Transkriptionsaktivitaet ist daher auch fuer die erhoehte neuronale Differenzierung. Interessanterweise konnten wir auch zeigen, dass Brahma-related gene 1 (Brg1), eine katalytische Untereinheit des SWI/SWF Komplexes, an den Ngn/CBP cotranscriptionalen Komplex bindet und dass diese Bindung durch LIF-Stimulation verstaerkt wurde. Dies suggeriert wiederum, dass auch Brg1 eine wichtige Rolle waehrend der murinen, cortikalen Neurogenese spielt. Dennoch, in folgenden Experimenten verblieb der Fokus auf Ngn und CBP. Um unsere Hypothese zu bestaetigen, dass PKCδ ein moeglicher Mediator des LIF-Effekts sein koennte, zeigten wir zunaechst, dass die PKCδ-Expression in cortikalen NPCs waehrend der Neurogenese erhoeht ist. Desweiteren demonstrierten wir, dass die Inhibition von PKCδ einen aehnliche Wirkung zeigte wie die Inhibition von PKC mit einem generellen PKC Inhibitor: weder war nach PKCδ-Inhibition eine LIF-induzierte NeuroD-Transkription erzielbar, noch wurde nach LIF-Stimulation der pro-neurale Marker class III β-tubulin/TuJ1 in Ngn1-infizierten NPCs exprimiert. Um aber mehr spezifisch die PKC- und PKCδ-Aktivitaet/Expression zu blockieren transfizierten wir NPCs mit PLCγ oder PKCδ siRNA. Unsere Daten zeigten hierbei, dass siRNA-transfizierte Zellen kein class III β-tubulin mehr aufweisen, was darauf hindeuted, dass PKCδ der potentielle Mediator des pro-neuralen LIF-Effekts ist. Durch unsere in vivo Daten demonstrierten wir schliesslich, dass LIF auch hierbei fuer die Neurogenese von Bedeutung ist. Verglichen wurden die Cortices von E13 LIF Het (heterozygote) und KO (knock out) Maeusen mit denen von WT (wild type) Maeusen. Durch Immunohistologie von Hirnschnitten konnten dabei keine groesseren Unterschiede bezueglich der Expression neuraler Marker beobachtet werden, waehrend aber mit Hilfe der Western Blot Analyse, eine quantitativere Methode, gezeigt wurde, dass LIF Het und KO Maeuse weniger pro-neurale Marker im Cortex exprimieren wie WT Mause. Um auch zu beweisen, dass dies auf eine verringerte Transkription von NeuroD zurueckzufuehren ist, demonstrierten wir mit Hilfe des ChIP Assay, dass LIF Het und KO Maeuse weniger Ngn1-CBP Bindung an den NeuroD-Promoter aufweisen wie WT Maeuse. Diese Experimente veranschaulichen einen eleganten Regulationsmechanismus, durch welchen ein einzelner, extrazellulaerer Faktor die unterschiedliche Differenzierung einer Zelle verstaerkt, abhaengig von der Anwesenheit oder Abwesenheit eines einzelnenn intrazellulaeren Faktors. Auch koennen durch die erlangten Resultate Strategien entworfen werden, durch die in Zukunft die Produktion bestimmter Neurone zur Heilung von verschiedenen, neurodegenerativen Krankheiten erhoeht wird.