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- 311781 (1)
Für BMPs wie auch die anderen Mitglieder der TGF-beta-Superfamilie beginnt der Signalweg mit der Bindung des Liganden an zwei Typen transmembranärer Rezeptoren. Die Ligand-Rezeptor Interaktionen sind dabei durch unterschiedliche Affinität und Spezifität gekennzeichnet und bilden wahrscheinlich die Grundlage für das breite Spektrum biologischer Funktionen. In dieser Arbeit wurde mittels einer Struktur- und Funktionsanalyse von BMP Ligand-Rezeptor Komplexen die molekulare Basis für die Affinität und Spezifität dieser Wechselwirkungen untersucht. Hierfür wurde die Kristallstruktur des BMP-2 : BR-IAec Ligand-Rezeptor Komplexes bei einer Auflösung von 1,9Å ermittelt. Mit der höheren Auflösung war die Charakterisierung der geometrischen Parameter eines Netzwerks von zehn Wasserstoff-Brückenbindungen in der Interaktionsfläche zwischen BMP-2 und BR-IAec möglich. Deren zentrale Bedeutung für dieWechselwirkung konnte auch durch funktionelle Analyse bestätigt werden. So stellen die im Zentrum der Bindungsfläche liegenden Wasserstoff-Brückenbindungen BMP-2 Leu51 (N) : BR-IAec Gln86 (OE1) und BMP-2 Leu51 (O) : BR-IAec Gln86 (NE1), sowie die BMP-2 Asp53 (N) : BR-IAec Cys77 (O) H-Brücke die Hauptdeterminanten der Ligand-Rezeptor Bindung dar. Darüber hinaus ließ sich aus der strukturellen Analyse des "wrist"-Epitops von BMP-2 eine besondere Bedeutung der Prä-Helix Schleife L2, sowie der im Kontakt eingeschlossenen Wassermoleküle für die Anpassung der Bindungsfläche an unterschiedliche Interaktionspartner ableiten. Diese Ergebnisse bilden die Grundlage für ein neues Modell zur Beschreibung von Affinität und Spezifität der hochaffinen BMP-Typ I Rezeptor Interaktion. Dabei stellen die Wasserstoff-Brückenbindungen den Hauptanteil zur Bindungsenergie, während die hydrophobe Umgebung in der Interaktionsfläche die Bildung von Wasserstoff-Brückenbindungen energetisch begünstigen und hydrophobe Wechselwirkungen nur geringfügigen Einfluss auf die Affinität nehmen. Die vorliegenden Arbeit beschreibt zudem die Präparation und Kristallisation von binären Ligand-Typ I Rezeptor Komplexen für BMP-2, BMP-6 und GDF-5, sowie die der ternären Komplexe von BMP-2, BR-IAec und ActR-IIec bzw. BR-IIec. Die extrazellulären Domänen der hierfür verwendeten Rezeptoren wurden durch Expression in E.coli oder Sf-9 Insektenzellen erhalten. Ihre funktionelle Charakterisierung erfolgte durch BIAcore Interaktionsanalyse an immobilisierten Liganden, wobei in Abhängigkeit vom Ligand-Rezeptor Komplex unterschiedliche Affinitäten ermittelt werden konnten. In Übereinstimmung mit den hierbei erhaltenen Daten wurden die Ligand-BMP Typ IB Rezeptor Komplexe für BMP-2, BMP-6 und GDF-5, sowie der GDF-5 : BR-IAec Ligand-Rezeptor Komplex präpariert. Des Weiteren konnte die Bildung des ternären BMP-2 : BR-IAec : ActR-IIec Ligand-Rezeptor Komplexes in Lösung nachgewiesen werden. Für all diese Komplexe konnten Kristallisationsbedingungen ermittelt werden. Trotz Optimierung dieser Bedingungen reichte die Qualität der erhaltenen Kristalle nicht für eine Aufklärung der Struktur aus. Für eine detailliertes Verständnis der Mechanismen der Rezeptoraktivierung muss die strukturelle und funktionelle Charakterisierung von BMP Ligand-Rezeptor Komplexen fortgeführt werden. Die präsentierten Ergebnisse deuten darauf hin, dass über die Kenntnis der einzelnen Affinitäten und die gezielte Modifikation der Interaktionspartner eine erfolgreiche Strukturanalyse dieser Ligand-Rezeptor Komplexe möglich ist.
Interleukin-4 (IL-4) und Interleukin-13 (IL-13) sind bedeutende Regulatorproteine des Immunsystems. Sie spielen eine entscheidende Rolle bei der Entstehung und dem Verlauf von allergischen Erkrankungen, wie z.B. Asthma. Um ihre Signale in die Zielzelle zu transduzieren, kann von beiden Zytokinen der gleiche Zelloberflächenrezeptor verwendet werden, wodurch sich die überlappenden, biologischen Funktionen erklären lassen. Dieser gemeinsam genutzte Rezeptor ist aus den beiden Untereinheiten IL-4Ralpha; und IL-13Ralpha1 aufgebaut. Da IL-4 und IL-13 auf Aminosäureebene nur etwa 25% Sequenzidentität besitzen und stark unterschiedliche Affinitäten zu den beiden Rezeptorketten besitzen, stellt sich die Frage, durch welchen molekularen Erkennungsmechanismus, die Affinität und die Spezifität der Ligand-Rezeptor-Interaktion unabhängig voneinander reguliert werden kann. In dieser Arbeit gelang es, rekombinante Expressions- und Aufreinigungsstrategien für IL-13 und die extrazellulären Domänen der Rezeptorketten IL-13Ralpha1 und IL-13Ralpha2 zu entwickeln. Dadurch war es mögliche, eine breite Mutations-/Interaktionsanalyse der IL-13Ralpha1-Kette durchzuführen.Es konnte gezeigt werden, dass die N-terminale FnIII-ähnliche Domäne von IL-13Ralpha1 sowohl an der Bindung von IL-13 als auch an der Interaktion mit IL-4 beteiligt ist. Im funktionellen Bindeepitop der IL-13Ralpha1-Kette wurden die Aminosäurereste Arg84, Phe253 und Tyr321 als Hauptbindungsdeterminanten für die Interaktion mit IL-13 identifiziert. Durch die Interaktionsstudien der IL-13Ralpha1-Varianten mit IL-4 wurde gezeigt, dass diese Hauptbindungsdeterminanten auch für die niederaffine Bindung von IL-4 von größter Bedeutung sind. Die funktionellen Bindeepitope für IL-4 und IL-13 auf der IL-13Ralpha1-Kette sind nahezu identisch und überlappen in einem großen Bereich. Aufgrund der Ergebnisse aus der Mutagenesestudie war es möglich, ein Strukturmodell der extrazellulären Domäne der IL-13Ralpha1-Kette zu erstellen. Darin wird eine neuartige Orientierung der N-terminalen FnIII-Domäne und deren Beteiligung an der Ligandeninteraktion dargestellt. Mit Hilfe des Strukturmodells gelang es, neue Aminosäurerest auf der Oberfläche von IL-13 zu identifizieren, die an der Bindung zu IL-13Ralpha1 beteiligt sind, was die Relevanz des Strukturmodells weiter unterstreicht. In einem weiteren Teil dieser Arbeit wurde versucht, den molekularen Mechanismus aufzuklären, durch den es den superagonistischen IL-4-Varianten T13D und F82D gelingt, mit dreifach höherer Affinität an die IL-4Ralpha-Kette zu binden, als wildtypischer Ligand. Durch strukturelle und funktionelle Untersuchungen wurde gezeigt, dass der Affinitätssteigerung ein indirekter Mechanismus zugrunde liegt, bei dem eine Konformationsänderung und die Fixierung der Arg85-Seitenkette von IL-4 zur Ausbildung von zusätzlichen Ligand-Rezeptor-Interaktionen führt. Das Bindeepitop zwischen IL-4 und der IL-4Ralpha-Kette besitzt eine modulare Architektur aus drei unabhängig voneinander agierenden Interaktionsclustern. Bei der Interaktion von wildtypischem IL-4 mit IL-4Ralpha tragen nur zwei dieser Cluster in signifikanter Weise zur freien Bindeenergie bei. Im Falle der superagonistischen IL-4-Varianten ist jedoch auch das dritte Cluster an der Generierung von zusätzlicher, freier Bindeenergie beteiligt, wodurch die Affinität zwischen Ligand und Rezeptor erhöht wird. Damit stellt der modulare Aufbau der Interaktionsfläche zwischen IL-4 und der IL-4Ralpha-Kette möglicherweise einen Mechanismus dar, über den Proteine die Affinität von Wechselwirkungen über einen großen Bereicht variieren können, ohne dabei Spezifität einzubüssen. Da IL-4 und IL-13 als interessante Zielmoleküle für die Therapie von allergischen und asthmatischen Erkrankungen erkannt worden sind, können die in der vorliegenden Arbeit gewonnenen Informationen über den Bindemechanismus und die Einblicke in den molekularen Charakter der Interaktion zwischen den beiden Zytokinen und ihren spezifischen Rezeptorketten dabei helfen, neuartige und hoch spezifische, inhibitorische Moleküle zu entwickeln.
This work deals with channel-tunnel dependent multidrug efflux pumps and type I secretion systems, more concrete with the improved classification of the adaptor protein family, the characterization of the TolC-homologue protein HI1462 of Haemophilus influenzae, and the molecular characterization of the interaction between TolC and AcrA of Escherichia coli.
Study of Omp85 Family Proteins YaeT and YtfM and Multidrug Export Machineries in Escherichia coli
(2006)
In this study the Omp85 family proteins YaeT and YtfM of Escherichia coli were investigated by using biochemical and electrophysiological methods as well as bioinformatical and structural analysis. In addition, knock-out strains were constructed to further study the relevance of these proteins in vivo. The prediction that Omp85 proteins are composed of two domains, a periplasmic amino-terminal POTRA (polypeptide translocation associated) domain and a carboxy-terminal domain anchoring these proteins in the outer membrane, was confirmed by the construction of mutants. It could be shown that the carboxy-terminal part of the proteins is able to insert into the outer bacterial membrane, even if the POTRA domain is removed. Furthermore, pore-forming activity in the black-lipid bilayer was observed for both full-length proteins as well as their carboxy-terminal membrane located parts. The channels formed by both proteins in the black lipid bilayer showed variable single channel conductance states rather than a defined value for conductance. In 1M KCl, e.g. YaeT forms pores with a channel conductance of 100 to 600 pS containing a most abundant value at 400 pS. This variability is at least reasonable for YaeT due to a prerequisite flexibility of its channel for OMP insertion. YaeT was identified to form a cation selective, YtfM an anion selective channel, which is less pH dependent than YaeT. Another feature of the YaeT channel is that its selectivity and conductance is influenced by charged detergent molecules indicating an accumulation of these molecules in hydrophobic pockets inside the compact channel. YaeT revealed heat-modifiable mobility in SDS-PAGE which is characteristic for β-barrel OMPs, whereas YtfM did not show this behaviour. This result could be explained by sequence alignment and structural comparison of YaeT and YtfM via CD and FTIR spectra displaying much higher β-strand content for the carboxy-terminal part of YaeT compared to YtfM. Since the carboxy-terminal parts were shown to have pore forming ability and are inserted in the OM in vivo, the substitution of the essential protein YaeT by its carboxy-terminal mutant was attempted in a yaeT knock-out strain. The carboxy-terminal half of YaeT was not sufficient to compensate depletion of the full-length protein indicating an important role of the amino-terminus for cell viability. In contrary, YtfM is shown to be a non-essential protein and lack of YtfM had no effects on the composition and integrity of the OM. However, chromosomal deletion of ytfM remarkably reduced the growth rate of cells. This study provides the first detailed investigation of the structure of YaeT and describes its electrophysiological behaviour, which could be a basis for further studies of YaeT and its substrate proteins. Furthermore, YtfM was characterised and its in vivo function was investigated revealing YtfM as the second Omp85 family protein of importance in E. coli. In a second part of this study assembly and function of multidrug efflux pumps were investigated. Drug efflux pumps are tripartite export machineries in the cell envelope of Gram-negative bacteria conferring multidrug resistance and therefore causing severe problems for medical treatment of diseases. Protein structures of all three efflux pump components are solved, but the exact interaction sites are still unknown. Assembly of a hybrid exporter system composed of the Pseudomonas aeruginosa channel tunnel OprM, the E. coli adaptor protein AcrA and its associated transporter AcrB could be shown by chemical cross-linking, even though this efflux pump is not functional. Exchange of the hairpin domain of AcrA by the corresponding hairpin from the adaptor protein MexA of P. aeruginosa restored functionality tested by antibiotic sensitivity assays. This shows the importance of the MexA hairpin domain for functional interaction with the OprM channel tunnel. Interestingly, the hybrid protein was also able to assemble with TolC as outer membrane component to form a functional efflux pump indicating a higher flexibility of TolC compared to OprM concerning interaction partners. Based on these results, an interaction model of the hairpin domain and the channel tunnel on molecular level for AcrA and TolC as well as MexA and OprM, respectively, is presented. This model provides a basis for directed mutagenesis to reveal the exact contact sites of the hairpin of the adapter protein and the outer membrane component
Study of the properties of channel-forming proteins of the cell walls of different Corynebacteriae
(2008)
The genus Corynebacterium belongs, together with Mycobacterium, Nocardia, Rhodococcus and further closely related genera, to the distinctive suprageneric taxon mycolata. Many species within this diverse group of mycolic acid containing actinomycetes are known either because of their medical or biotechnological relevance. For instance, Mycobacterium tuberculosis, Mycobacterium leprae, Corynebacterium diphtheriae and Nocardia farcinica, causer of most dangerous bacterial infectious diseases world-wide, are among this exceptional group of Gram-positive bacteria. Likewise of importance are some harmless mycolata species which find use in industrial settings. Corynebacterium glutamicum and Corynebacterium efficiens are, e.g., potent producers of the flavour enhancer glutamate and the animal feed additive lysine, while several Rhodococcus species are applied in the production of acrylic acids. The cell wall of mycolata species, compared with that of Gram-positive bacteria, exhibits an unusual composition and organization. Besides an arabinogalactan-peptidoglycan complex, the cell walls of most actinomycetes contain large amounts of mycolic acids. Comparable to the outer membrane of Gram-negative bacteria, these long-chained branched fatty acids form a highly impermeable hydrophobic outer layer which provides the basis of the exceptional drug resistance of mycolata species. Like the outer membrane of Gram-negative bacteria, the cell wall of mycolata contains channel-forming proteins that allow the passage of hydrophilic solutes. By permitting and controlling the exchange and communication between the interior of the cell and the environment in which the bacterium lives, the channels play an important role for the function of the bacterial cell envelope. This thesis aimed to extend our knowledge about cell wall channels in corynebacteria. For this purpose, we examined PorA and PorH proteins that have been associated by previous studies with cell wall pores in C. glutamicum, C. efficiens and Corynebacterium callunae in order to resolve unanswered questions and to gain structural knowledge. We also investigated cell walls of pathogenic corynebacteria, in particular of Corynebacterium diphtheriae and Corynebacterium jeikeium, to investigate if these species possessed channels as is the case with their harmless relatives. In this work we provided evidence for the existence of large and water-filled cell wall channels in C. diphtheriae and C. jeikeium. Moreover, we demonstrated that the major cell wall channels of C. glutamicum, C. efficiens and C. diphtheriae consist of two distinctive polypeptides; one of whom belongs to the class of PorH proteins and the other to the class of PorA proteins. This heteromeric structure of channels of corynebacteria represents a novelty for channels of the mycolata. In contrast, the C. jeikeium channel is solely constituted by a single protein, CjPorA, arranged as an oligomer. Although the molecular mass of this protein (4kDa) is comparable to those of PorH and PorA proteins (5-7 kDa), it shares no distinctive homology in its primary sequence with them. However, there is evidence for relationship between CjPorA and PorH/PorA proteins because the gene jk0268, coding for CjPorA, is localized in a chromosomal region of C. jeikeium that corresponds to the genomic region containing the porH/porA genes in the other corynebacteria. This suggests that jk0268 (coding for the homomeric cell wall channel in C. jeikeium) and the porH/porA genes of C. glutamicum, C. efficiens and C. diphtheriae (coding for heteromeric cell wall channels) are presumably descendants of a common ancestor gene. This assumption gets support from data on phylogenetic analysis of the genus Corynebacterium. Moreover, these data suggest that the here investigated cell wall channels are presumably widespread within this genus. A profound knowledge of cell wall channels, building the main passage of solutes through the outer mycolate membrane in corynebacteria and other members of the mycolata, can be of great economical and medical value.
In the eusocial insect honeybee (Apis mellifera), many sterile worker bees live together with a reproductive queen in a colony. All tasks of the colony are performed by the workers, undergoing age-dependent division of labor. Beginning as hive bees, they take on tasks inside the hive such as cleaning or the producing of larval food, later developing into foragers. With that, the perception of sweetness plays a crucial role for all honeybees whether they are sitting on the honey stores in the hive or foraging for food. Their ability to sense sweetness is undoubtedly necessary to develop and evaluate food sources. Many of the behavioral decisions in honeybees are based on sugar perception, either on an individual level for ingestion, or for social behavior such as the impulse to collect or process nectar. In this context, honeybees show a complex spectrum of abilities to perceive sweetness on many levels. They are able to perceive at least seven types of sugars and decide to collect them for the colony. Further, they seem to distinguish between these sugars or at least show clear preferences when collecting them. Additionally, the perception of sugar is not rigid in honeybees. For instance, their responsiveness towards sugar changes during the transition from in-hive bees (e.g. nurses) to foraging and is linked to the division of labor. Other direct or immediate factors changing responsiveness to sugars are stress, starvation or underlying factors, such as genotype.
Interestingly, the complexity in their sugar perception is in stark contrast to the fact that honeybees seem to have only three predicted sugar receptors.
In this work, we were able to characterize the three known sugar receptors (AmGr1, AmGr2 and AmGr3) of the honeybee fully and comprehensively in oocytes (Manuscript II, Chapter 3 and Manuscript III, Chapter 4). We could show that AmGr1 is a broad sugar receptor reacting to sucrose, glucose, maltose, melezitose and trehalose (which is the honeybees’ main blood sugar), but not fructose. AmGr2 acts as its co-receptor altering AmGr1’s specificity, AmGr3 is a specific fructose receptor and we proved the heterodimerization of all receptors. With my studies, I was able to reproduce and compare the ligand specificity of the sugar receptors in vivo by generating receptor mutants with CRISPR/Cas9. With this thesis, I was able to define AmGr1 and AmGr3 as the honeybees’ basis receptors already capable to detect all sugars of its known taste spectrum.
In the expression analysis of my doctoral thesis (Manuscript I, Chapter 2) I demonstrated that both basis receptors are expressed in the antennae and the brain of nurse bees and foragers. This thesis assumes that AmGr3 (like the Drosophila homologue) functions as a sensor for fructose, which might be the satiety signal, while AmGr1 can sense trehalose as the main blood sugar in the brain. Both receptors show a reduced expression in the brain of foragers when compared with nurse bees. These results may reflect the higher concentrated diet of nurse bees in the hive. The higher number of receptors in the brain may allow nurse bees to perceive hunger earlier and to consume the food their sitting on. Forager bees have to be more persistent to hunger, when they are foraging, and food is not so accessible. The findings of reduced expression of the fructose receptor AmGr3 in the antennae of nurse bees are congruent with my other result that nurse bees are also less responsive to fructose at the antennae when compared to foragers (Manuscript I, Chapter 2). This is possible, since nurse bees sit more likely on ripe honey which contains not only higher levels of sugars but also monosaccharides (such as fructose), while foragers have to evaluate less-concentrated nectar.
My investigations of the expression of AmGr1 in the antennae of honeybees found no differences between nurse bees and foragers, although foragers are more responsive to the respective sugar sucrose (Manuscript I, Chapter 2). Considering my finding that AmGr2 is the co-receptor of AmGr1, it can be assumed that AmGr1 and the mediated sucrose taste might not be directly controlled by its expression, but indirectly by its co-receptor. My thesis therefore clearly shows that sugar perception is associated with division of labor in honeybees and appears to be directly or indirectly regulated via expression.
The comparison with a characterization study using other bee breeds and thus an alternative protein sequence of AmGr1 shows that co-expression of different AmGr1 versions with AmGr2 alters the sugar response differently. Therefore, this thesis provides first important indications that alternative splicing could also represent an important regulatory mechanism for sugar perception in honeybees.
Further, I found out that the bitter compound quinine lowers the reward quality in learning experiments for honeybees (Manuscript IV, Chapter 5). So far, no bitter receptor has been found in the genome of honeybees and this thesis strongly assumes that bitter substances such as quinine inhibit sugar receptors in honeybees. With this finding, my work includes other molecules as possible regulatory mechanism in the honeybee sugar perception as well. We showed that the inhibitory effect is lower for fructose compared to sucrose. Considering that sugar signals might be processed as differently attractive in honeybees, this thesis concludes that the sugar receptor inhibition via quinine in honeybees might depend on the receptor (or its co-receptor), is concentration-dependent and based on the salience or attractiveness and concentration of the sugar present.
With my thesis, I was able to expand the knowledge on honeybee’s sugar perception and formulate a complex, comprehensive overview. Thereby, I demonstrated the multidimensional mechanism that regulates the sugar receptors and thus the sugar perception of honeybees. With this work, I defined AmGr1 and AmGr3 as the basis of sugar perception and enlarged these components to the co-receptor AmGr2 and the possible splice variants of AmGr1. I further demonstrated how those sugar receptor components function, interact and that they are clearly involved in the division of labor in honeybees. In summary, my thesis describes the mechanisms that enable honeybees to perceive sugar in a complex way, even though they inhere a limited number of sugar receptors. My data strongly suggest that honeybees overall might not only differentiate sugars and their diet by their general sweetness (as expected with only one main sugar receptor). The found sugar receptor mechanisms and their interplay further suggest that honeybees might be able to discriminate directly between monosaccharides and disaccharides or sugar molecules and with that their diet (honey and nectar).
Sugar reward learning in Drosophila : neuronal circuits in Drosophila associative olfactory learning
(2006)
Genetic intervention in the fly Drosophila melanogaster has provided strong evidence that the mushroom bodies of the insect brain act as the seat of memory traces for aversive and appetitive olfactory learning (reviewed in Heisenberg, 2003). In flies, electroshock is mainly used as negative reinforcer. Unfortunately this fact complicates a comparative consideration with other inscets as most studies use sugar as positive reinforcer. For example, several lines of evidence from honeybee and moth have suggested another site, the antennal lobe, to house neuronal plasticity underlying appetitive olfactory memory (reviewed in Menzel, 2001; Daly et al., 2004). Because of this I focused my work mainly on appetitive olfactory learning. In the first part of my thesis, I used a novel genetic tool, the TARGET system (McGuire et al., 2003), which allows the temporally controlled expression of a given effector gene in a defined set of cells. Comparing effector genes which either block neurotransmission or ablate cells showed important differences, revealing that selection of the appropriate effector gene is critical for evaluating the function of neural circuits. In the second part, a new engram of olfactory memory in the Drosophila projection neurons is described by restoring Rutabaga adenlylate cyclase (rut-AC) activity specifically in these cells. Expression of wild-type rutabaga in the projection neurons fully rescued the defect in sugar reward memory, but not in aversive electric shock memory. No difference was found in the stability of the appetitive memories rescued either in projection neurons or Kenyon cells. In the third part of the thesis I tried to understand how the reinforcing signals for sugar reward are internally represented. In the bee Hammer (1993) described a single octopaminergic neuron – called VUMmx1 – that mediates the sugar stimulus in associative olfactory reward learning. Analysis of single VUM neurons in the fly (Selcho, 2006) identified a neuron with a similar morphology as the VUMmx1 neuron. As there is a mutant in Drosophila lacking the last enzymatic step in octopamine synthesis (Monastirioti et al., 1996), Tyramine beta Hydroxylase, I was able to show that local Tyramine beta Hydroxylase expression successfully rescued sugar reward learning. This allows to conclude that about 250 cells including the VUM cluster are sufficient for mediating the sugar reinforcement signal in the fly. The description of a VUMmx1 similar neuron and the involvement of the VUM cluster in mediating the octopaminergic sugar stimulus are the first steps in establishing a neuronal map for US processing in Drosophila. Based on this work several experiments are contrivable to reach this ultimate goal in the fly. Taken together, the described similiarities between Drosophila and honeybee regarding the memory organisation in MBs and PNs and the proposed internal representation of the sugar reward suggest an evolutionarily conserved mechanism for appetitive olfactory learning in insects.
Sumoylation of transcription factors modulate their activity (either upregulating or downregulating) by altering protein-protein interactions as well as subcelluar/subnuclear localization. The transcription factor family of NFAT (Nuclear Factor of Activated T cells) plays an important role in cytokine gene regulation in T cells. Due to alternative usage of two promoters (P1 & P2), two polyadenylation sites (pA1 and pA2) and alternative splicing events, NFATc1 is expressed in six isoforms which are NFATc1/alphaA, betaA, alphaB, betaB, alphaC and betaC, where alpha and beta refer to two different 1st exons and A, B, C to the differentially spliced and extended C-termini. The short isoforms of NFATc1 (NF-ATc1/A) contain a relatively short C terminus whereas, the longer isoforms, B and C, span the extra C-terminal peptides of 128 and 246 aa, respectively. To analyze the specific biological effects of NFATc1 isoform, a yeast two hybrid screening of a human spleen cDNA library with extra C-terminal peptide of NFATc1 as a bait, was performed. At the end of the assay, the proteins involved in the sumoylation pathway such as Ubc9, PIAS1 were detected with highest frequencies and subsequently were were able to demonstrate that NFATc1 is sumoylated. The extent of sumoylation is isoform specific. While NFATc1/A, harboring only one sumoylation site, shows very weak sumoylation, the two additional sites within NFATc1/C lead to efficient sumoylation. This modification directs NFATc1/C into SUMO-1 bodies, which in turn colocalize with PML-nbs. Furthermore, sumoylated NFATc1/C recruits the transcriptional co-repressors HDAC (both class I as well as class II HDACs) which results in a significant decrease of the level of histone acetylation on the IL-2 promoter, an important NFATc1 target gene. As a consequence of this, a decrease of IL-2 production was observed, while NFATc1/C, which can no longer be sumoylated due to mutating the target lysines, exhibited dramatic elevated transcriptional potential on the IL2 promoter. This supports our finding from IL-2 promoter-driven reporter gene assay, which shows downregulation of NFATc1/C transactivation upon sumoylation. Hence, sumoylation exerts a negative effect on NFATc1 transcriptioanl activity. Immunofluorescence studies showed SUMO modification to relocate NFATc1/C also into transcriptionally inactive heterochromatin regions, demonstrated by H3K9 m3 (tri-methylated histone lysine 9) colocalization studies. Interestingly, in the absence of sumoylation, NFATc1 was partially colocalized with transcriptional hotspots in the nucleus, which might contribute to the higher transcription potentiality of the non-sumoylated NFATc1. It is important to note that, the transcriptional activity of other NFATc1 target genes (IL-13, IFN-gamma etc.) was positively upregulated upon sumoylation of NFATc1, suggesting a non-universal effect of sumoylation on NFATc1/C function. In conclusion, sumoylation directs NFATc1 into nuclear bodies where it interacts with transcriptional co-repressors and relocalize itself with heterochromatin, leading to repression of NFATc1/C-mediated transcription. Most importantly, the effect of NFATc1/C sumoylation is promoter specific. Taken together, SUMO modification alters the function of NFATc1 from an activator to a site-specific transcriptional repressor. This study unraveled a novel regulatory mechanism, which controls isoform specific NFATc1 function.
Plasma membrane receptors are the most crucial and most commonly studied components of cells, since they not only ensure communication between the extracellular space and cells, but are also responsible for the regulation of cell cycle and cell division. The composition of the surface receptors, the so-called "Receptome", differs and is characteristic for certain cell types. Due to their significance, receptors have been important target structures for diagnostic and therapy in cancer medicine and often show aberrant expression patterns in various cancers compared to healthy cells. However, these aberrations can also be exploited and targeted by different medical approaches, as in the case of personalized immunotherapy. In addition, advances in modern fluorescence microscopy by so-called single molecule techniques allow for unprecedented sensitive visualization and quantification of molecules with an attainable spatial resolution of 10-20 nm, allowing for the detection of both stoichiometric and expression density differences.
In this work, the single molecule sensitive method dSTORM was applied to quantify the receptor composition of various cell lines as well as in primary samples obtained from patients with hematologic malignancies. The focus of this work lies on artefact free quantification, stoichiometric analyses of oligomerization states and co localization analyses of membrane receptors.
Basic requirements for the quantification of receptors are dyes with good photoswitching properties and labels that specifically mark the target structure without generating background through non-specific binding. To ensure this, antibodies with a predefined DOL (degree of labeling) were used, which are also standard in flow cytometry. First background reduction protocols were established on cell lines prior analyses in primary patient samples. Quantitative analyses showed clear expression differences between the cell lines and the patient cells, but also between individual patients.
An important component of this work is the ability to detect the oligomerization states of receptors, which enables a more accurate quantification of membrane receptor densities compared to standard flow cytometry. It also provides information about the activation of a certain receptor, for example of FLT3, a tyrosine kinase, dimerizing upon activation. For this purpose, different well-known monomers and dimers were compared to distinguish the typical localization statistics of single bound antibodies from two or more antibodies that are in proximity. Further experiments as well as co localization analyses proved that antibodies can bind to closely adjacent epitopes despite their size.
These analytical methods were subsequently applied for quantification and visualization of receptors in two clinically relevant examples. Firstly, various therapeutically relevant receptors such as CD38, BCMA and SLAMF7 for multiple myeloma, a malignant disease of plasma cells, were analyzed and quantified on patient cells. Furthermore, the influence of TP53 and KRAS mutations on receptor expression levels was investigated using the multiple myeloma cell lines OPM2 and AMO1, showing clear differences in certain receptor quantities.
Secondly, FLT3 which is a therapeutic target receptor for acute myeloid leukemia, was quantified and stoichiometrically analyzed on both cell lines and patient cells. In addition, cells that have developed resistance against midostaurin were compared with cells that still respond to this type I tyrosine-kinase-inhibitor for their FLT3 receptor expression and oligomerization state.
Humans tend to believe in what they can see with their own eyes. Hence, visualization methods like microscopy have always been extremely popular since their invention in the 17th century. With the advent of super-resolution microscopy, the diffraction limit of ~200 - 250 nm could be overcome to enable more detailed insights into biological samples. Especially the single molecule localization microscopy method dSTORM offers the possibility of quantitative bioimaging. Hereby, the repetitive photoswitching of organic dyes in the presence of thiols is exploited to enable a lateral resolution of 20 nm. Another, recently introduced super-resolution method is expansion microscopy (ExM) which physically expands the sample to increase the resolution by the expansion factor from four to even twenty. To enable this, the sample is embedded into a hydrogel, homogenized using an unspecific proteinase and expanded in distilled water. Within this thesis, both methods were used to shed light on plasma membrane receptor distributions and different bacterial and fungal pathogens. In the first part of this thesis dSTORM was used to elucidate the “Receptome”, the entirety of all membrane receptors, of the cell line Jurkat T-cells and primary T-cells. Within this project we could successfully visualize and quantify the distribution of the plasma membrane receptors CD2, CD3, CD4, CD5, CD7, CD11a, CD20, CD28, CD45, CD69 and CD105 with receptor densities ranging from 0.8 cluster/µm² in case of CD20 and 81.4 cluster/µm² for the highly abundant CD45 in activated primary T-cells at the basal membrane. Hereby, we could also demonstrate a homogeneous distribution of most receptors, while only few were clustered. In the case of CD3-clusters were detected in Jurkat T-cells and in primary activated T-cells, but not in naïve ones, demonstrating the activation of this receptor. This was followed by the application of dSTORM to three different clinical projects involving the receptors CD38, BCMA and CD20 which are immunotherapeutic targets by monoclonal antibodies and CAR T-cells. In the first two projects dSTORM was applied to determine the receptor upregulation upon exposure of various drugs to MM1.S cells or primary multiple myeloma patient cells. This increase in membrane receptor expression can subsequently enhance the efficacy of therapies directed against these receptors. Within the CD20-project, the superior sensitivity of dSTORM compared to flow cytometry could be demonstrated. Hereby, a substantially higher fraction of CD20-positive patient cells was detected by dSTORM than by flow cytometry. In addition, we could show that by dSTORM CD20-positive evaluated cells were eradicated by immunotherapeutic CAR T-cell treatment. These studies were followed by whole cell super-resolution imaging using both LLS-3D dSTORM and 10x ExM to exclude any artifacts caused by interactions with the glass surface. In 10x ExM signal amplification via biotinylated primary antibodies and streptavidin ATTO 643 was essential to detect even single antibodies directed against the heterodimer CD11a with standard confocal microscopes. Albeit probably not quantitative due to the process of gelation, digestion and expansion during the ExM protocol, even some putative dimers of the receptor CD2 could be visualized using 10x ExM-SIM, similar to dSTORM experiments. Within the second part of this thesis, expansion microscopy was established in bacterial and fungal pathogens. ExM enabled not only an isotropic fourfold expansion of Chlamydia trachomatis, but also allowed the discrimination between the two developmental forms by the chlamydial size after expansion into reticulate and elementary bodies. Hereafter, a new α-NH2-ω-N3-C6-ceramide was introduced enabling an efficient fixation and for the first time the use of lipids in both, 4x and 10x ExM, termed sphingolipid ExM. This compound was used to investigate the ceramide uptake and incorporation into the cell membrane of Chlamydia trachomatis and Simkania negevensis. For Chlamydia trachomatis the combined resolution power of 10x ExM and SIM even allowed the visualization of both bacterial membranes within a distance of ~30 nm. Finally, ExM was applied to the three different fungi Ustilago maydis, Fusarium oxysporum and Aspergillus fumigatus after enzymatic removal of the fungal cell wall. In case of Ustilago maydis sporidia this digestion could be applied to both, living cells resulting in protoplasts and to fixed cells, preserving the fungal morphology. This new protocol could be demonstrated for immunostainings and fluorescent proteins of the three different fungi.
The interaction of synaptic proteins orchestrate the function of one of the most complex organs, the brain. The multitude of molecular elements influencing neurological correlations makes imaging processes complicated since conventional fluorescence microscopy methods are unable to resolve structures beyond the diffraction-limit.
The implementation of super-resolution fluorescence microscopy into the field of neuroscience allows the visualisation of the fine details of neural connectivity. The key element of my thesis is the super-resolution technique dSTORM (direct Stochastic Optical Reconstruction Microscopy) and its optimisation as a multi-colour approach. Capturing more than one target, I aim to unravel the distribution of synaptic proteins with nanometer precision and set them into a structural and quantitative context with one another. Therefore dSTORM specific protocols are optimized to serve the peculiarities of particular neural samples.
In one project the brain derived neurotrophic factor (BDNF) is investigated in primary, hippocampal neurons. With a precision beyond 15 nm, preand post-synaptic sites can be identified by staining the active zone proteins bassoon and homer. As a result, hallmarks of mature synapses can be exhibited. The single molecule sensitivity of dSTORM enables the measurement of endogenous BDNF and locates BDNF granules aligned with glutamatergic pre-synapses. This data proofs that hippocampal neurons are capable of enriching BDNF within the mature glutamatergic pre-synapse, possibly influencing synaptic plasticity.
The distribution of the metabotropic glutamate receptor mGlu4 is investigated in physiological brain slices enabling the analysis of the receptor in its natural environment. With dual-colour dSTORM, the spatial arrangement of the mGlu4 receptor in the pre-synaptic sites of parallel fibres in the molecular layer of the mouse cerebellum is visualized, as well as a four to six-fold increase in the density of the receptor in the active zone compared to the nearby environment. Prior functional measurements show that metabotropic glutamate receptors influence voltage-gated calcium channels and proteins that are involved in synaptic vesicle priming. Corresponding dSTORM data indeed suggests that a subset of the mGlu4 receptor is correlated with the voltage-gated calcium channel Cav2.1 on distances around 60 nm.
These results are based on the improvement of the direct analysis of localisation data. Tools like coordinated based correlation analysis and nearest neighbour analysis of clusters centroids are used complementary to map protein connections of the synapse. Limits and possible improvements of these tools are discussed to foster the quantitative analysis of single molecule localisation microscopy data.
Performing super-resolution microscopy on complex samples like brain slices benefits from a maximised field of view in combination with the visualisation of more than two targets to set the protein of interest in a cellular context. This challenge served as a motivation to establish a workflow for correlated structured illumination microscopy (SIM) and dSTORM. The development of the visualisation software coSIdSTORM promotes the combination of these powerful super-resolution techniques even on separated setups. As an example, synapses in the cerebellum that are affiliated to the parallel fibres and the dendrites of the Purkinje cells are identified by SIM and the protein bassoon of those pre-synapses is visualised threedimensionally with nanoscopic precision by dSTORM.
In this work I placed emphasis on the improvement of multi-colour super-resolution imaging and its analysing tools to enable the investigation of synaptic proteins. The unravelling of the structural arrangement of investigated proteins supports the building of a synapse model and therefore helps to understand the relation between structure and function in neural transmission processes.
Die Entwicklung hochauflösender Fluoreszenzmikroskopiemethoden hat die Lichtmikroskopie revolutioniert. Einerseits ermöglicht die höhere erzielte räumliche Auflösung die Abbildung von Strukturen, die deutlich unterhalb der beugungsbedingten Auflösungsgrenze liegen. Andererseits erhält man durch Einzelmoleküllokalisationsmikroskopiemethoden
wie dSTORM (Direct Stochastic Optical Reconstruction Microscopy) Informationen, welche man für quantitative Analysen heranziehen kann. Aufgrund der sich dadurch bietenden neuen Möglichkeiten, hat sich die hochauflösende Fluoreszenzmikroskopie rasant entwickelt und kommt mittlerweile zur Untersuchung einer Vielzahl biologischer und medizinischer Fragestellungen zum Einsatz. Trotz dieses Erfolgs ist jedoch nicht zu verleugnen, dass auch diese neuen Methoden ihre Nachteile haben. Dazu zählt die Notwendigkeit relativ hoher Laserleistungen, welche Voraussetzung für hohe Auflösung ist und bei lebenden Proben zur Photoschädigung führen kann.
Diese Arbeit widmet sich sowohl dem Thema der Photoschädigung durch Einzelmoleküllokalisationsmikroskopie,
als auch der Anwendung von dSTORM und SIM (Structured Illumination Microscopy) zur Untersuchung neurobiologischer Fragestellungen auf Proteinebene.
Zur Ermittlung der Photoschädigung wurden lebende Zellen unter typischen Bedingungen bestrahlt und anschließend für 20−24 h beobachtet. Als quantitatives Maß für den Grad der Photoschädigung wurde der Anteil sterbender Zellen bestimmt. Neben der zu erwartenden Intensitäts- und Wellenlängenabhängigkeit, zeigte sich, dass die Schwere der Photoschädigung auch von vielen weiteren Faktoren abhängt und dass sich Einzelmoleküllokalisationsmikroskopie bei Berücksichtigung der gewonnenen Erkenntnisse durchaus mit Lebendzellexperimenten vereinbaren lässt.
Ein weiteres Projekt diente der Untersuchung der A- und B-Typ-Glutamatrezeptoren an der neuromuskulären Synapse von Drosophila melanogaster mittels dSTORM. Dabei konnte eine veränderte Anordnung beider Rezeptortypen infolge synaptischer Plastizität beobachtet, sowie eine absolute Quantifizierung des A-Typ-Rezeptors durchgeführt werden.
Im Mittelpunkt eines dritten Projekts standen Cadherin-13 (CDH13) sowie der Glucosetransporter Typ 3 (GluT3), welche beide mit der Aufmerksamkeitsdefizit-Hyperaktivitätsstörung in Verbindung gebracht werden. CDH13 konnte mittels SIM in serotonergen Neuronen, sowie radiären Gliazellen der dorsalen Raphekerne des embryonalen Mausgehirns nachgewiesen werden. Die Rolle von GluT3 wurde in aus induzierten pluripotenten Stammzellen differenzierten Neuronen analysiert, welche verschiedene Kopienzahlvariation des für GluT3-codierenden SLC2A3-Gens aufwiesen. Die Proteine GluT3, Bassoon und Homer wurden mittels dSTORM relativ quantifiziert. Während die Deletion des Gens zu einer erwartenden Verminderung von GluT3 auf Proteinebene führte, hatte die Duplikation keinen Effekt auf die GluT3-Menge. Für Bassoon und Homer zeigte sich weder durch die Deletion noch die Duplikation eine signifikante Veränderung.
Owing to climate change, natural forest disturbances and consecutive salvage logging are drastically increasing worldwide, consequently increasing the importance of understanding how these disturbances would affect biodiversity conservation and provision of ecosystem services.
In chapter II, I used long-term water monitoring data and mid-term data on α-diversity of twelve species groups to quantify the effects of natural disturbances (windthrow and bark beetle) and salvage logging on concentrations of nitrate and dissolved organic carbon (DOC) in streamwater and α-diversity. I found that natural disturbances led to a temporal increase of nitrate concentrations in streamwater, but these concentrations remained within the health limits recommended by the World Health Organization for drinking water. Salvage logging did not exert any additional impact on nitrate and DOC concentrations, and hence did not affect streamwater quality. Thus, neither natural forest disturbances in watersheds nor associated salvage logging have a harmful effect on the quality of the streamwater used for drinking water. Natural disturbances increased the α-diversity in eight out of twelve species groups. Salvage logging additionally increased the α-diversity of five species groups related to open habitats, but decreased the biodiversity of three deadwood-dependent species groups.
In chapter III, I investigated whether salvage logging following natural disturbances (wildfire and windthrow) altered the natural successional trajectories of bird communities. I compiled data on breeding bird assemblages from nine study areas in North America, Europe and Asia, over a period of 17 years and tested whether bird community dissimilarities changed over time for taxonomic, functional and phylogenetic diversity when rare, common and dominant species were weighted differently. I found that salvage logging led to significantly larger dissimilarities than expected by chance and that these dissimilarities persisted over time for rare, common and dominant species, evolutionary lineages, and for rare functional groups. Dissimilarities were highest for rare, followed by common and dominant species.
In chapter IV, I investigated how β-diversity of 13 taxonomic groups would differ in intact, undisturbed forests, disturbed, unlogged forests and salvage-logged forests 11 years after a windthrow and salvage logging. The study suggests that both windthrow and salvage logging drive changes in between-treatment β-diversity, whereas windthrow alone seems to drive changes in within-treatment β-diversity. Over a decade after the windthrow at the studied site, the effect of subsequent salvage logging on within-treatment β-diversity was no longer detectable but the effect on between-treatment β-diversity persisted, with more prominent changes in saproxylic groups and rare species than in non-saproxylic groups or common and dominant species.
Based on these results, I suggest that salvage logging needs to be carefully weighed against its long-lasting impact on communities of rare species. Also, setting aside patches of naturally disturbed areas is a valuable management alternative as these patches would enable post-disturbance succession of bird communities in unmanaged patches and would promote the conservation of deadwood-dependent species, without posing health risks to drinking water sources.
Switches in trypanosome differentiation: ALBA proteins acting on post-transcriptional mRNA control
(2011)
Trypanosoma brucei is a digenetic eukaryotic parasite that develops in different tissues of a mammalian host and a tsetse fly. It is responsible for sleeping sickness in sub-saharan Africa. The parasite cycle involves more than nine developmental stages that can be clearly distinguished by their general morphology, their metabolism and the relative positioning of their DNA-containing organelles. During their development, trypanosomes remain exclusively extracellular and encounter changing environments with different physico-chemical properties (nutritional availability, viscosity, temperature, etc.). It has been proposed that trypanosomes use their flagellum as a sensing organelle, in agreement with the established role of structurally-related cilia in metazoa and ciliates. Recognition of environmental triggers is presumed to be at the initiation of differentiation events, leading to the parasite stage that is the best suited to the new environment. These changes are achieved by the modification of gene expression programmes, mostly underlying post-transcriptional control of mRNA transcripts. We first demonstrate that the RNA-binding proteins ALBA3/4 are involved in specific differentiation processes during the parasite development in the fly. They are cytosolic and expressed throughout the parasite cycle with the exception of the stages found in the tsetse fly proventriculus, as shown by both immunofluorescence and live cell analysis upon endogenous tagging with YFP. Knock-down of both proteins in the developmental stage preceding these forms leads to striking modifications: cell elongation, cell cycle arrest and relocalization of the nucleus in a posterior position, all typical of processes acting in parasites found in the proventriculus region. When ALBA3 is over-expressed from an exogenous copy during infection, it interferes with the relocalization of the nucleus in proventricular parasites. This is not observed for ALBA4 over-expression that does not visibly impede differentiation. Both ALBA3/4 proteins react to starvation conditions by accumulating in cytoplasmic stress granules together with DHH1, a recognized RNA-binding protein. ALBA3/4 proteins also partially colocalize with granules formed by polyA+ RNA in these conditions. We propose that ALBA are involved in trypanosome differentiation processes where they control a subset of developmentally regulated transcripts. These processes involving ALBA3/4 are likely to result from the specific activation of sensing pathways. In the second part of the thesis, we identify novel flagellar proteins that could act in sensing mechanisms. Several protein candidates were selected from a proteomic analysis of intact flagella performed in the host laboratory. This work validates their flagellar localization with high success (85% of the proteins examined) and defines multiple different patterns of protein distribution in the flagellum. Two proteins are analyzed during development, one of them showing down-regulation in proventricular stages. The functional analysis of one novel flagellar membrane protein reveals its rapid dynamics within the flagellum but does not yield a visible phenotype in culture. This is coherent with sensory function that might not be needed in stable culture conditions, but could be required in natural conditions during development. In conclusion, this work adds new pieces to the puzzle of identifying molecular switches involved in developmental mRNA control and environmental sensing in trypanosome stages in the tsetse fly.
SYCE3, ein neues Synaptonemalkomplexprotein: Expression, funktionelle Analyse und Bindungspartner
(2011)
Der Synaptonemalkomplex ist eine evolutionär hoch konservierte Struktur. Er wird spezifisch während der Prophase I der Meiose ausgebildet und ist essentiell für die Segregation der homologen Chromosomen während der Meiose und auch für die Entstehung genetischer Vielfalt. Der Synaptonemalkomplex ist eine proteinöse Struktur, deren Aufbau dem einer Leiter ähnelt. Dabei werden die Leiterholme als Lateralelemente bezeichnet. Sie bestehen unter anderem aus den Proteinen SYCP2 und SYCP3 und assoziieren mit dem Chromatin der homologen Chromosomen. Die Stufen der Leiter bestehen hingegen aus Transversalfilamenten, deren Hauptkomponente parallele Homodimere des meiosespezifische Proteins SYCP1 sind. Dabei wird ein SYCP1 Dimer mit seinem C-Terminus in den Lateralelementen verankert und kann über seine N-terminale Domäne eine schwache Interaktion mit der N-terminalen Domäne eines gegenüberliegenden SYCP1 Dimers eingehen. Um diese Bindung zu stabilisieren werden Proteine des Zentralelements des Synaptonemalkomplexes benötigt: Während SYCE1 durch seine Interaktion mit SYCP1 die N-terminale Assoziation zweier gegenüberliegender SYCP1 Dimere stabilisiert, verknüpfen die zwei anderen zentralelementspezifischen Proteine SYCE2 und Tex12 lateral benachbarte SYCP1 Filamente und breiten so das SYCP1 Netzwerk entlang der chromosomalen Achsen aus. Dieser Prozess wird als Synapse bezeichnet und stellt eines der Schlüsselereignisse der Meiose dar. Fehler während dieses Prozesses führen meist zu Aneuploidie der entstehenden Gameten oder zum Abbruch der Meiose und somit zu Infertilität des betroffenen Organismus. In dieser Arbeit wurde mit SYCE3 ein neues Protein des murinen Synaptonemalkomplexes charakterisiert. Es konnte gezeigt werden, dass SYCE3 meiosespezifisch in Männchen und Weibchen exprimiert wird und Bestandteil des Zentralelements des Synaptonemalkomplexes ist. Hierbei zeigt es dasselbe Verteilungsmuster wie SYCP1 und SYCE1 und kann mit beiden Proteinen interagieren. Eine zusätzliche Interaktion konnte zwischen SYCE3 und SYCE2 nachgewiesen werden. Durch Untersuchungen an entsprechenden Knockout Mausmodellen konnte in dieser Arbeit außerdem gezeigt werden, dass SYCE3 in Abwesenheit von SYCP1 nicht an die chromosomalen Achsen rekrutiert werden kann. Die Ausbildung der Lateralelemente und auch die Anwesenheit der anderen zentralelementspezifischen Proteine SYCE1 und SYCE2 sind hingegen für die Anlagerung von SYCE3 an die chromosomalen Achsen nicht essentiell. Somit steht SYCE3 hinsichtlich seiner Bedeutung für die Paarung und die Synapse der homologen Chromosomen hierarchisch offenbar über den bisher beschriebenen Zentralelementproteinen SYCE1, SYCE2 und Tex12. Die funktionelle Bedeutung von SYCE3 für die Synapse der homologen Chromosomen und für den korrekten Ablauf der homologen Rekombination wurde im Rahmen dieser Arbeit durch die Herstellung und die Charakterisierung einer Syce3-/- Maus detailliert untersucht: Dabei führte der Knockout von SYCE3 zur Infertilität in beiden Geschlechtern, die gleichzeitig mit einer signifikanten Reduktion der Größe der entsprechenden Hoden und Ovarien im Vergleich zum Wildtyp einherging. Weitere Untersuchungen ergaben zudem, dass es in Syce3 defizienten Tieren zu einem Abbruch der Meiose kommt. Dabei hatte das Fehlen von SYCE3 keinen Einfluss auf die Ausbildung der Axialelemente. Die Initiation der Synapse hingegen war sowohl in Oocyten als auch in Spermatocyten in Abwesenheit von SYCE3 stark gestört. Darüber hinaus konnte in der vorliegenden Arbeit nachgewiesen werden, dass das Fehlen von SYCE3 Einfluss auf die homologe Rekombination nimmt: Zwar können sich frühe (DNA Doppelstrangbrüche) und intermediäre (Transitionsknoten) Rekombinationsereignisse in der Abwesenheit von SYCE3 ausbilden, die Prozessierung zu späten Rekombinationsstrukturen (Rekombinationsknoten) und die damit einhergehende Ausbildung von Crossing-over Strukturen fand jedoch nicht statt. Zusammengefasst wurde in dieser Arbeit gezeigt, dass das neue Synaptonemalkomplexprotein SYCE3 essentiell für die Fertilität von Mäusen ist. Durch den Knockout von Syce3 kann die Synapse zwischen den Homoligen nicht initiiert werden und es findet kein Crossing-over statt. Im Assembly Prozess des Synaptonemalkomplexes agiert SYCE3 oberhalb der anderen zentralelementspezifischen Proteine und unterhalb von SYCP1.
Memory is dynamic: shortly after acquisition it is susceptible to amnesic treatments, gets gradually consolidated, and becomes resistant to retrograde amnesia (McGaugh, 2000). Associative olfactory memory of the fruit fly Drosophila melanogaster also shows these features. After a single associative training where an odor is paired with electric shock (Quinn et al., 1974; Tully and Quinn, 1985), flies form an aversive odor memory that lasts for several hours, consisting of qualitatively different components. These components can be dissociated by mutations, their underlying neuronal circuitry and susceptibility to amnesic treatments (Dubnau and Tully, 1998; Isabel et al., 2004; Keene and Waddell, 2007; Masek and Heisenberg, 2008; Xia and Tully, 2007). A component that is susceptible to an amnesic treatment, i.e. anesthesia-sensitive memory (ASM), dominates early memory, but decays rapidly (Margulies et al., 2005; Quinn and Dudai, 1976). A consolidated anesthesia-resistant memory component (ARM) is built gradually within the following hours and lasts significantly longer (Margulies et al., 2005; Quinn and Dudai, 1976). I showed here that the establishment of ARM requires less intensity of shock reinforcement than ASM. ARM and ASM rely on different molecular and/or neuronal processes: ARM is selectively impaired in the radish mutant, whereas for example the amnesiac and rutabaga genes are specifically required for ASM (Dudai et al., 1988; Folkers et al., 1993; Isabel et al., 2004; Quinn and Dudai, 1976; Schwaerzel et al., 2007; Tully et al., 1994). The latter comprise the cAMP signaling pathway in the fly, with the PKA being its supposed major target (Levin et al., 1992). Here I showed that a synapsin null-mutant encoding the evolutionary conserved phosphoprotein Synapsin is selectively impaired in the labile ASM. Further experiments suggested Synapsin as a potential downstream effector of the cAMP/PKA cascade. Similar to my results, Synapsin plays a role for different learning tasks in vertebrates (Gitler et al., 2004; Silva et al., 1996). Also in Aplysia, PKA-dependent phosphorylation of Synapsin has been proposed to be involved in regulation of neurotransmitter release and short-term plasticity (Angers et al., 2002; Fiumara et al., 2004). Synapsin is associated with a reserve pool of vesicles at the presynapse and is required to maintain vesicle release specifically under sustained high frequency nerve stimulation (Akbergenova and Bykhovskaia, 2007; Li et al., 1995; Pieribone et al., 1995; Sun et al., 2006). In contrast, the requirement of Bruchpilot, which is homologous to the mammalian active zone proteins ELKS/CAST (Wagh et al., 2006), is most pronounced in immediate vesicle release (Kittel et al., 2006). Under repeated stimulation of a bruchpilot mutant motor neuron, immediate vesicle release is severely impaired whereas the following steady-state release is still possible (Kittel et al., 2006). In line with that, knockdown of the Bruchpilot protein causes impairment in clustering of Ca2+ channels to the active zones and a lack of electron-dense projections at presynaptic terminals (T-bars). Thus, less synaptic vesicles of the readily-releasable pool are accumulated to the release sites and their release probability is severely impaired (Kittel et al., 2006; Wagh et al., 2006). First, I showed that Bruchpilot is required for aversive olfactory memory and localized the requirement of Bruchpilot to the Kenyon cells of the mushroom body, the second-order olfactory interneurons in Drosophila. Furthermore, I demonstrated that Bruchpilot selectively functions for the consolidated anesthesia-resistant memory. Since Synapsin is specifically required for the labile anesthesia sensitive memory, different synaptic proteins can dissociate consolidated and labile components of olfactory memory and two different modes of neurotransmission (high- vs. low frequency dependent) might differentiate ASM and ARM.
Endogenous clocks regulate physiological as well as behavioral rhythms within all organisms. They are well investigated in D. melanogaster on a molecular as well as anatomical level. The neuronal clock network within the brain represents the center for rhythmic activity control. One neuronal clock subgroup, the pigment dispersing factor (PDF) neurons, stands out for its importance in regulating rhythmic behavior. These neurons express the neuropeptide PDF (pigment dispersing factor). A small neuropil at the medulla’s edge, the accessory medulla (AME), is of special interest, as it has been determined as the main center for clock control. It is not only highly innervated by the PDF neurons but also by terminals of all other clock neuron subgroups. Furthermore, terminals of the photoreceptors provide light information to the AME. Many different types of neurons converge within the AME and afterward spread to their next target. Thereby the AME is supplied with information from a variety of brain regions. Among these neurons are the aminergic ones whose receptors’ are expressed in the PDF neurons. The present study sheds light onto putative synaptic partners and anatomical arrangements within the neuronal clock network, especially within the AME, as such knowledge is a prerequisite to understand circadian behavior. The aminergic neurons’ conspicuous vicinity to the PDF neurons suggests synaptic communication among them. Thus, based on former anatomical studies regarding this issue detailed light microscopic studies have been performed. Double immunolabellings, analyses of the spatial relation of pre- and postsynaptic sites of the individual neuron populations with respect to each other and the identification of putative synaptic partners using GRASP reenforce the hypothesis of synaptic interactions within the AME between dopaminergic/ serotonergic neurons and the PDF neurons. To shed light on the synaptic partners I performed first steps in array tomography, as it allows terrific informative analyses of fluorescent signals on an ultrastructural level. Therefore, I tested different ways of sample preparation in order to achieve and optimize fluorescent signals on 100 nm thin tissue sections and I made overlays with electron microscopic images. Furthermore, I made assumptions about synaptic modulations within the neuronal clock network via glial cells. I detected their cell bodies in close vicinity to the AME and PDFcontaining clock neurons. It has already been shown that glial cells modulate the release of PDF from s-LNvs’ terminals within the dorsal brain. On an anatomical level this modulation appears to exist also within the AME, as synaptic contacts that involve PDF-positive dendritic terminals are embedded into glial fibers. Intriguingly, these postsynaptic PDF fibers are often VIIAbstract part of dyadic or even multiple-contact sites in opposite to prolonged presynaptic active zonesimplicating complex neuronal interactions within the AME. To unravel possible mechanisms of such synaptic arrangements, I tried to localize the ABC transporter White. Its presence within glial cells would indicate a recycling mechanism of transmitted amines which allows their fast re-provision. Taken together, synapses accompanied by glial cells appear to be a common arrangement within the AME to regulate circadian behavior. The complexity of mechanisms that contribute in modulation of circadian information is reflected by the complex diversity of synaptic arrangements that involves obviously several types of neuron populations
Learning and memory is considered to require synaptic plasticity at presynaptic specializations of neurons. Kenyon cells are the intrinsic neurons of the primary olfactory learning center in the brain of arthropods – the mushroom body neuropils. An olfactory mushroom body memory trace is supposed to be located at the presynapses of Kenyon cells. In the calyx, a sub-compartment of the mushroom bodies, Kenyon cell dendrites receive olfactory input provided via projection neurons. Their output synapses, however, were thought to reside exclusively along their axonal projections outside the calyx, in the mushroom body lobes. By means of high-resolution imaging and with novel transgenic tools, we showed that the calyx of the fruit fly Drosophila melanogaster also comprised Kenyon cell presynapses. At these presynapses, synaptic vesicles were present, which were capable of neurotransmitter release upon stimulation. In addition, the newly identified Kenyon cell presynapses shared similarities with most other presynapses: their active zones, the sites of vesicle fusion, contained the proteins Bruchpilot and Syd-1. These proteins are part of the cytomatrix at the active zone, a scaffold controlling synaptic vesicle endo- and exocytosis. Kenyon cell presynapses were present in γ- and α/β-type KCs but not in α/β-type Kenyon cells.
The newly identified Kenyon cell derived presynapses in the calyx are candidate sites for an olfactory associative memory trace. We hypothesize that, as in mammals, recurrent neuronal activity might operate for memory retrieval in the fly olfactory system.
Moreover, we present evidence for structural synaptic plasticity in the mushroom body calyx. This is the first demonstration of synaptic plasticity in the central nervous system of Drosophila melanogaster. The volume of the mushroom body calyx can change according to changes in the environment. Also size and numbers of microglomeruli - sub-structures of the calyx, at which projection neurons contact Kenyon cells – can change. We investigated the synapses within the microglomeruli in detail by using new transgenic tools for visualizing presynaptic active zones and postsynaptic densities. Here, we could show, by disruption of the projection neuron - Kenyon cell circuit, that synapses of microglomeruli were subject to activity-dependent synaptic plasticity. Projection neurons that could not generate action potentials compensated their functional limitation by increasing the number of active zones per microglomerulus. Moreover, they built more and enlarged microglomeruli. Our data provide clear evidence for an activity-induced, structural synaptic plasticity as well as for the activity-induced reorganization of the olfactory circuitry in the mushroom body calyx.
Desert ants of the genus Cataglyphis have become model systems for the study of insect navigation. An age-related polyethism subdivides their colonies into interior workers and short-lived light-exposed foragers. While foraging in featureless and cluttered terrain over distances up to several hundred meters, the ants are able to precisely return back to their often inconspicuous nest entrance. They accomplish this enormous navigational performance by using a path integration system - including a polarization compass and an odometer - as their main navigational means in addition to landmark-dependent orientation and olfactory cues. C. fortis, being the focus of the present thesis, is endemic to the salt flats of western North Africa, which are completely avoided by other Cataglyphis species. The fact that Cataglyphis ants undergo a behavioral transition associated with drastically changing sensory demands makes these ants particularly interesting for studying synaptic plasticity in visual and olfactory brain centers. This thesis focuses on plastic changes in the mushroom bodies (MBs) - sensory integration centers supposed to be involved in learning and memory presumably including landmark learning - and in synaptic complexes belonging to the lateral accessory lobe (LAL) known to be a relay station in the polarization processing pathway. To investigate structural synaptic plasticity in the MBs of C. fortis, synaptic complexes (microglomeruli, MG) in the visual (collar) and olfactory (lip) input regions of the MB calyx were immunolabeled and their pre- and postsynaptic profiles were quantified. The results show that a volume increase of the MB calyx during behavioral transition is associated with a decrease of MG number - an effect called pruning - in the collar and, less pronounced, in the lip that goes along with dendritic expansion in MB intrinsic Kenyon cells. Light-exposure of dark-reared ants of different age classes revealed similar effects and dark-reared ants age-matched to foragers had MG numbers comparable to those of interior workers. The results indicate that the enormous structural synaptic plasticity of the MB calyx collar is primarily driven by visual experience rather than by an internal program. Ants aged artificially for up to one year expressed a similar plasticity indicating that the system remains flexible over the entire life-span. To investigate whether light-induced synaptic reorganization is reversible, experienced foragers were transferred back to darkness with the result that their MBs exhibit only some reverse-type characteristics, in particular differences in presynaptic synapsin expression. To investigate the structure of large synaptic complexes in the LAL of C. fortis and to detect potential structural changes, pre- and postsynaptic profiles in interior workers and foragers were immunolabeled and quantified by using confocal imaging and 3D-reconstruction. The results show that these complexes consist of postsynaptic processes located in a central region that is surrounded by a cup-like presynaptic profile. Tracer injections identified input and output tracts of the LAL: projection neurons from the anterior optic tubercle build connections with neurons projecting to the central complex. The behavioral transition is associated with an increase by ~13% of synaptic complexes suggesting that the polarization pathway may undergo some sort of calibration process. The structural features of these synaptic contacts indicate that they may serve a fast and reliable signal transmission in the polarization vision pathway. Behavioral analyses of C. fortis in the field revealed that the ants perform exploration runs including pirouette-like turns very close to the nest entrance for a period of up to two days, before they actually start their foraging activity. During these orientation runs the ants gather visual experience and might associate the nest entrance with specific landmarks or get entrained to other visual information like the polarization pattern, and, concomitantly adapt their neuronal circuitries to the upcoming challenges. Moreover, the pirouettes may serve to stimulate and calibrate the neuronal networks involved in the polarization compass pathway. Video recordings and analyses demonstrate that light experience enhanced the ants’ locomotor activity after three days of exposure. The fact that both the light-induced behavioral and neuronal changes in visual brain centers occur in the same time frame suggests that there may be a link between structural synaptic plasticity and the behavioral transition from interior tasks to outdoor foraging. Desert ants of the genus Cataglyphis possess remarkable visual navigation capabilities, but also employ olfactory cues for detecting nest and food sites. Using confocal imaging and 3D-reconstruction, potential adaptations in primary olfactory brain centers were analyzed by comparing the number, size and spatial arrangement of olfactory glomeruli in the antennal lobe of C. fortis, C. albicans, C. bicolor, C. rubra, and C. noda. Workers of all Cataglyphis species have smaller numbers of glomeruli compared to those of more olfactory-guided Formica species - a genus closely related to Cataglyphis - and to those previously found in other olfactory-guided ant species. C. fortis has the lowest number of glomeruli compared to all other species, but possesses a conspicuously enlarged glomerulus that is located close to the antennal nerve entrance. Males of C. fortis have a significantly smaller number of glomeruli compared to female workers and queens and a prominent male-specific macroglomerulus likely to be involved in sex pheromone communication. The behavioral significance of the enlarged glomerulus in female workers remains elusive. The fact that C. fortis inhabits microhabitats that are avoided by all other Cataglyphis species suggests that extreme ecological conditions may not only have resulted in adaptations of visual capabilities, but also in specializations of the olfactory system. The present thesis demonstrates that Cataglyphis is an excellent candidate for studying the neuronal mechanisms underlying navigational features and for studying neuronal plasticity associated with the ant’s lifelong flexibility of individual behavioral repertoires.
Synaptonemal Komplexe (SC) sind evolutionär konservierte, meiosespezifische, proteinöse Strukturen, die maßgeblich an Synapsis, Rekombination und Segregation der homologen Chromosomen beteiligt sind. Sie zeigen eine dreigliedrige strickleiter-artige Organisation, die sich aus i) zwei Lateralelementen (LE), an die das Chromatin der Homologen angelagert ist, ii) zahlreichen Transversalfilamenten (TF), welche die LE in einer reißverschlussartigen Weise miteinander verknüpfen, und iii) einem zentralen Element (CE) zusammensetzt. Die Hauptproteinkomponenten der Säuger-SC sind das Transversalfilamentprotein SYCP1 und die Lateralelementproteine SYCP2 und SYCP3. Wie sich die SC-Struktur zusammenfügt war bisher nur wenig verstanden; es war nicht bekannt wie die TF innerhalb der LE-Strukturen verankert sind und dabei die homologen Chromosomen verknüpfen. Aufgrund dessen wurde die Interaktion zwischen den Proteinen SYCP1 und SYCP2 untersucht. Mit der Hilfe verschiedenster Interaktionssysteme konnte gezeigt werden, dass der C-Terminus von SYCP1 mit SYCP2 interagieren kann. Aufgrund der Bindungsfähigkeit zu beiden Proteinen, SYCP1 und SYCP3, kann angenommen werden, dass SYCP2 als Linker zwischen diesen Proteinen fungiert und somit möglicherweise das fehlende Bindungsglied zwischen den Lateralelementen und Transversalfilamenten darstellt. Obwohl die SC-Struktur in der Evolution hochkonserviert ist, schien dies nicht für seine Protein-Untereinheiten zuzutreffen. Um die Struktur und Funktion des SC besser verstehen zu können, wurde ein Vergleich zwischen den orthologen SYCP1 Proteinen der evolutionär entfernten Spezies Ratte und Medaka erstellt. Abgesehen von den erheblichen Sequenzunterschieden die sich in 450 Millionen Jahren der Evolution angehäuft haben, traten zwei bisher nicht identifizierte Sequenzmotive hervor, CM1 und CM2, die hochgradig konserviert sind. Anhand dieser Motive konnte in Datenbankanalysen erstmals ein Protein in Hydra vulgaris nachgewiesen werden, bei dem es sich um das orthologe Protein von SYCP1 handeln könnte. Im Vergleich mit dem SYCP1 der Ratte zeigten die Proteine aus Medaka und Hydra, neben den hoch konservierten CM1 und CM2, vergleichbare Domänenorganisationen und im heterologen System zudem sehr ähnliche Polymerisationseigenschaften. Diese Ergebnisse sprechen für eine evolutionäre Konservierung von SYCP1.