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Olfaction plays an important role in a variety of behaviors throughout the life of the European honeybee. Caste specific, environmentally induced and aging/experiencedependent differences in olfactory behavior represent a promising model to investigate mechanisms and consequences of phenotypic neuronal plasticity within the olfactory pathway of bees. This study focuses on the two different female phenotypes within the honeybee society, queens and workers. In this study, for the first time, structural plasticity in the honeybee brain was investigated at the synaptic level. Queens develop from fertilized eggs that are genetically not different from those that develop into workers. Adult queens are larger than workers, live much longer, and display different behaviors. Developmental trajectory is mainly determined by nutritional factors during the larval period. Within the subsequent post-capping period, brood incubation is precisely controlled, and pupae are incubated close to 35°C via thermoregulatory activity of adult workers. Behavioral studies suggest that lower rearing temperatures cause deficits in olfactory learning in adult bees. To unravel possible neuronal correlates for thermoregulatory and caste dependent influences on olfactory behavior, I examined structural plasticity of developing as well as mature olfactory synaptic neuropils. Brood cells were reared in incubators and pupal as well as adult brains were dissected for immunofluorescent staining. To label synaptic neuropils, I used an antibody to synapsin and fluophore-conjugated phalloidin which binds to filamentous (F-) actin. During development, neuronal F-actin is expressed in growing neurons, and in the mature nervous system, F-actin is most abundant in presynaptic terminals and dendritic spines. In the adult brains, this double labeling technique enables the quantification of distinct synaptic complexes microglomeruli [MG]) within olfactory and visual input regions of the mushroom bodies (MBs) prominent higher sensory integration centers. Analyses during larval-adult metamorphosis revealed that the ontogenetic plasticity in the female castes is reflected in the development of the brain. Distinct differences among the timing of the formation of primary and secondary olfactory neuropils were also revealed. These differences at different levels of the olfactory pathway in queens and workers correlate with differences in tasks performed by both female castes. In addition to caste specific differences, thermoregulation of sealed brood cells has important consequences on the synaptic organization within the MB calyces of adult workers and queens. Even small differences in rearing temperatures affected the number of MG in the olfactory calyx lip regions. In queens, the highest number of MG in the olfactory lip developed at 1°C below the temperature where the maximum of MG is found in workers (33.5 vs. 34.5°C). Apart from this developmental neuronal plasticity, this study exhibits a striking age-related plasticity of MG throughout the extended life span of queens. Interestingly, MG numbers in the olfactory lip increased with age, but decreased within the adjacent visual collar of the MB calyx. To conclude, developmental and adult plasticity of the synaptic circuitry in the sensory input regions of the MB calyx may underlie caste- and age-specific adaptations and long-term plasticity in behavior.
In this century new experimental and computational techniques are adding an enormous amount of information, revealing many biological mysteries. The complexities of biological systems still broach new questions. Till now the main approach to understand a system has been to divide it in components that can be studied. The upcoming new paradigm is to combine the pieces of information in order to understand it at a global level. In the present thesis we have tried to study infectious diseases with such a global ‘Systems Biology’ approach. In the first part the apoptosis pathway is analyzed. Apoptosis (Programmed cell death) is used as a counter measure in different infections, for example viral infections. The interactions between death domain containing proteins are studied to address the following questions: i) How specificity is maintained - showing that it is induced through adaptors, ii) how proliferation/ survival signals are induced during activation of apoptosis – suggesting the pivotal role of RIP. The model also allowed us to detect new possible interacting surfaces. The pathway is then studied at a global level in a time step simulation to understand the evolution of the topology of activators and inhibitors of the pathway. Signal processing is further modeled in detail for the apoptosis pathway in M. musculus to predict the concentration time course of effector caspases. Further, experimental measurements of caspase-3 and viability of cells validate the model. The second part focuses on the phagosome, an organelle which plays an essential role in removal of pathogens as exemplified by M. tuberculosis. Again the problem is addressed in two main sections: i) To understanding the processes that are inhibited by M. tuberculosis; we focused on the phospholipid network applying a time step simulation in section one, which plays an important role in inhibition or activation of actin polymerization on the phagosome membrane. ii) Furthermore, actin polymers are suggested to play a role in the fusion of the phagosome with lysosome. To check this hypothesis an in silico model was developed; we find that the search time is reduced by 5 fold in the presence of actin polymers. Further the effect of length of actin polymers, dimensions of lysosome, phagosome and other model parameter is analyzed. After studying a pathway and then an organelle, the next step was to move to the system. This was exemplified by the host pathogen interactions between Bordetella pertussis and Bordetella bronchiseptica. The limited availability of quantitative information was the crucial factor behind the choice of the model type. A Boolean model was developed which was used for a dynamic simulation. The results predict important factors playing a role in Bordetella pathology especially the importance of Th1 related responses and not Th2 related responses in the clearance of the pathogen. Some of the quantitative predictions have been counterchecked by experimental results such as the time course of infection in different mutants and wild type mice. All these computational models have been developed in presence of limited kinetic data. The success of these models has been validated by comparison with experimental observations. Comparative models studied in chapters 6 and 9 can be used to explore new host pathogen interactions. For example in chapter 6, the analysis of inhibitors and inhibitory paths in three organism leads to the identification of regulatory hotspots in complex organisms and in chapter 9 the identification of three phases in B. bronchiseptica and inhibition of IFN-γ by TTSS lead us to explore similar phases and inhibition of IFN-γ in B. pertussis. Further an important significance of these models is to identify new components playing an essential role in host-pathogen interactions. In silico deletions can point out such components which can be further analyzed by experimental mutations.
Diese Arbeit untersucht zelluläre Netzwerke mit dem Ziel, die so gewonnenen Einsichten medizinisch beziehungsweise biotechnologisch zu nutzen. Hierzu müssen zunächst Proteindomänen und wichtige regulatorische RNA Elemente erkannt werden. Dies geschieht für regulatorische Elemente in Nukleinsäuren am Beispiel von Iron Responsive Elements (IREs) in Staphylococcus aureus, wobei sich solche Elemente in viel versprechender Nähe zu exprimierten Sequenzen finden lassen (T. Dandekar, F. Du, H. Bertram (2001) Nonlinear Analysis 47(1): 225-34). Noch bedeutsamer als Ziele zur Medikamentenentwicklung gegen Parasiten sind Domänenunterschiede in Struktur und Sequenz bei Proteinen (T. Dandekar, F. Du, H. Bertram (2001) Nonlinear Analysis 47(1): 225-34). Ihre Identifikation wird am Beispiel eines potentiellen Transportproteins in Plasmodium falciparum exemplarisch dargestellt. Anschließend wird das Zusammenwirken von regulatorischen Elementen und Domänen in Netzwerken betrachtet (einschließlich experimenteller Daten). Dies kann einerseits zu allgemeineren Schlussfolgerungen über das Netzwerkverhalten führen, andererseits für konkrete Anwendungen genutzt werden. Als Beispiel wählten wir hier Redoxnetzwerke und die Bekämpfung von Plasmodien als Verursacher der Malaria. Da das gesamte Redoxnetzwerk einer lebenden Zelle mit Methoden der pH Wert Messung nur unzureichend zu erfassen ist, werden als alternative Messmethode für dieses Netzwerk Mikrokristalle der Glutathionreduktase als Indikatorsystem nach digitaler Verstärkung experimentell genutzt (H. Bertram, M. A. Keese, C. Boulin, R. H. Schirmer, R. Pepperkok, T. Dandekar (2002) Chemical Nanotechnology Talks III - Nano for Life Sciences). Um komplexe Redoxnetzwerke auch bioinformatisch zu modulieren, werden Verfahren der metabolischen Fluxanalyse vorgestellt und verbessert, um insbesondere ihrer Verzahnung besser gerecht zu werden und solche Netzwerke mit möglichst wenig elementaren Flussmoden zutreffend beschreiben zu können. Die Reduktion der Anzahl von Elementarmoden bei sehr großen metabolischen Netzwerken einer Zelle gelingt hier mit Hilfe unterschiedlicher Methoden und führt zu einer vereinfachten Darstellungsmöglichkeit komplexer Stoffwechselwege von Metaboliten. Dabei dient bei jeder dieser Methoden die biochemisch sinnvolle Definition von externen Metaboliten als Grundlage (T. Dandekar, F. Moldenhauer, S. Bulik, H. Bertram, S. Schuster (2003) Biosystems 70(3): 255-70). Allgemeiner werden Verfahren der Proteindomänenklassifikation sowie neue Strategien gegen mikrobielle Erreger betrachtet. In Bezug auf automatisierte Einteilung von Proteinen in Domänen wird ein neues System von Taylor (2002b) mit bekannten Systemen verglichen, die in unterschiedlichem Umfang menschlichen Eingriffs bedürfen (H. Bertram, T. Dandekar (2002) Chemtracts 15: 735-9). Außerdem wurde neben einer Arbeit über die verschiedenen Methoden aus den Daten eines Genoms Informationen über das metabolische Netzwerk der Zelle zu erlangen (H. Bertram, T. Dandekar (2004) it 46(1): 5-11) auch eine Übersicht über die Schwerpunkte der Bioinformatik in Würzburg zusammengestellt (H. Bertram, S. Balthasar, T. Dandekar (2003) Bioforum 1-2: 26-7). Schließlich wird beschrieben, wie die Pathogenomik und Virulenz von Bakterien der bioinformatischen Analyse zugänglich gemacht werden können (H. Bertram, S. Balthasar, T. Dandekar (2003) Bioforum Eur. 3: 157-9). Im letzten Teil wird die metabolische Fluxanalyse zur Identifikation neuer Strategien zur Bekämpfung von Plasmodien dargestellt: Beim Vergleich der Stoffwechselwege mit Glutathion und Thioredoxin in Plasmodium falciparum, Anopheles und Mensch geht es darum, gezielte Störungen im Stoffwechsel des Malariaerregers auszulösen und dabei den Wirt zu schonen. Es ergeben sich einige interessante Ansatzpunkte, deren medizinische Nutzung experimentell angestrebt werden kann.
Die Lamine gehören zu einer Familie von Proteinen, die als strukturelle Hauptelemente die Kernlamina ausbilden, einen wesentlichen Bestandteil der Kernhülle eukaryontischer Zellen. In Säugern exprimieren differenzierte somatische Zellen die Lamine A, C, B1 und B2. Die Kernhülle in Keimzellen unterscheidet sich in Bezug auf Struktur und Proteinzusammensetzung deutlich von der einer somatischen Zelle. So exprimieren Keimzellen Lamin B1 als einziges der somatischen Lamine und zwei kurze keimbahnspezifische Spleißvarianten, die Lamine C2 und B3. Die vorliegende Arbeit enthält eine detaillierte Analyse des Expressionsmusters und der zellulären Verteilung von Lamin B3 im Verlauf der Spermatogenese der Maus. Die Daten aus RT-PCR, Western Blot und Immunfluoreszenz belegen eindeutig, dass Lamin B3 ausschließlich in postmeiotischen Stadien während der Spermiogenese exprimiert wird. In runden Spermatiden konnte das Protein an der Kernhülle und überraschenderweise auch im Nukleoplasma nachgewiesen werden. Im weiteren Verlauf der Spermiogenese kommt es zu einer Umverteilung des Proteins, es konzentriert sich zunehmend am posterioren Pol des Spermatidenkerns. Damit ist die Lamina während der Säuger-Spermiogenese nur aus B-Typ-Laminen aufgebaut und Lamin B3 ist in Säugern das erste Beispiel für ein Lamin, das selektiv nur in postmeiotischen Stadien der Spermatogenese exprimiert wird. Die ektopische Expression von Lamin B3 in Kulturzellen führt zu einer Deformation der Zellkerne, die eine hakenförmige Gestalt annehmen. Mit Hilfe von Transfektionsexperimenten in COS-7-Zellen konnte eindeutig gezeigt werden, dass die auftretenden morphologischen Veränderungen der Kerne transfizierter Zellen auf die trunkierte zentrale Stäbchendomäne in Lamin B3 zurückzuführen ist. Darüber hinaus zeigte das Protein eine stark erhöhte Löslichkeit im Vergleich zu Lamin B2 und die Analyse transfizierter Kulturzellen mit „fluorescence recovery after photobleaching“ (FRAP) und „fluorescence loss in photobleaching“ (FLIP) ergab, dass ein erheblicher Anteil der Lamin-B3-Moleküle eine hohe Mobilität aufweist, die ebenfalls ausschließlich durch die kurze Stäbchendomäne begründet ist. Die Ergebnisse führen zu dem Schluss, dass Lamin B3 die Kernhülle in Keimzellen flexibler macht, was eine Voraussetzung für einige Vorgänge in der Spermiogenese sein könnte. Mit einem Fusionsprotein aus GST und dem 84 Aminosäuren umfassenden N-Terminus von Lamin B3 wurde über einen „Pull-Down-Assay“ nach möglichen Interaktionspartnern in Keimzellen gesucht. Mit MSY2, MSY2a und MSY4 wurden drei hoch interessante Kandidaten identifiziert. Sie gehören zu den Y-Box-Proteinen, DNA- und RNA-bindende Proteine, die bei der Speicherung und späteren Translation von mRNAs beteiligt sind, u.a. die mRNA von Protamin 1 (diese Form der Regulation von Genexpression hat in der Spermatogenese große Bedeutung). Die Interaktion von Lamin B3 mit diesen Proteinen muss noch überprüft werden, würde aber einen weiteren Bezug zwischen Kernhülle und Chromatinreorganisation in der Spermiogenese herstellen, wie es für die Kernhüllenproteine GCL und LBR bereits gezeigt werden konnte. Außerdem wäre es ein erster Hinweis auf eine funktionelle Bedeutung der N-terminalen Domäne von Lamin B3.
In this study pore forming proteins of the gram-negative bacteria B. burgdorferi, B. duttonii and E.coli were investigated. Therefore the study is subdivided into three parts. In the first part outer membrane preparation of three relapsing fever Borrelia were investigated. In the second part the putative TolC homologue BB0124 of B. burgdorferi, the Lyme borreliosis agent, was studied. In the last part the influence of point mutants within the greasy slide of the maltose specific porin (LamB) of E. coli were shown. In the first part of this study outer membrane preparations of three Borrelia relapsing fever strains have been studied for pore-forming activity in the black lipid bilayer assay. Histograms of conductance fluctuations were obtained from single-channel experiments with outer membrane preparations of B. hermsii, B. recurentis and B. duttonii. All strains had a different conductance fluctuation pattern with a broad range of single-channel conductance values varying from 0.5 nS – 11 nS. Common for all three strains was a high pore-forming activity at around 0.5 nS. Furthermore the proteins of the outer membrane of B. duttonii were separated by chromatographic methods. Some eluate fractions contained a channel-forming protein, which was forming stable channels with a single-channel conductance of 80 pS in 1 M KCl. Characterization of this channel showed that it is slightly anionic selective and voltage independent. The small single-channel conductance suggests that it is a specific pore. However, a substrate specificity could not be determined. In the second part, for the B. burgdorferi HB19 and p66 knock out strain HB19/K02, their outer membrane preparations were characterized in the black lipid bilayer assay. Comparing the histograms of single-channel conductions fluctuations of both strains showed no single-channel activity at 11.5 nS for the p66 knock out strain. This verifies earlier studies that P66 is a pore-forming protein in B. burgdorferi. Furthermore, one fraction obtained by anion exchange chromatography of the p66 knock out outer membrane protein preparation showed a uniform channel-forming activity with a single channel conductance of 300 pS. The electrophysically characterization of the 300 pS channel showed that it is not ionselective or voltage dependent. By mass spectrometry using peptide mass finger prints, BB0142 could be identified as the sole channel forming candidate in the active fraction. A BLAST search and a conserved domain search showed that BB0142 is a putative TolC homologue in B. burgdorferi. Furthermore the location of the bb0142 gene within the chromosome is in an operon encoding a multidrug efflux pump. In this study the expression of an outer membrane component of a putative drug efflux system of B. burgdorferi was shown for the first time. In the third part functional studies of the maltooligosaccharide-specific LamB channel were performed. The 3D-structure of LamB suggests that a number of aromatic residues (Y6, Y41, W74, F229, W358 and W420) within the channel lumen is involved in carbohydrate and ion transport. All aromatic residues were replaced by alanine (A) scanning mutagenesis. Furthermore, LamB mutants were created in which one, two, three, four and five aromatic residues were replaced to study their effects on ion and maltopentaose transport through LamB. The purified mutant proteins were reconstituted into lipid bilayer membranes and the single-channel conductance was studied. The results suggest that all aromatic residues provide some steric hindrance for ion transport through LamB. Highest impact is provided by Y6 and Y41, which are localized opposite to Y118, which forms the central constriction of the LamB channel. Stability constants for binding of maltopentaose to the mutant channels were measured using titration experiments with the carbohydrate. The mutation of one or several aromatic amino acids led to a substantial decrease of the stability constant of binding. The highest effect was observed when all aromatic amino acids were replaced by alanine because no binding of maltopentaose could be detected in this case. However, binding was again possible when Y118 was replaced by tryptophane (W). The carbohydrate-induced block of the channel function could also be used for the study of current noise through the different mutant LamB-channels. The analysis of the power density spectra of some of the mutants allowed the evaluation of the on- and off-rate constants (k1 and k-1) of carbohydrate binding to the binding-site inside the channels. The results suggest that both on- and off-rate constants were affected by the mutations. For most mutants k1 decreased and k-1 increased.
Insights into the evolution of protein domains give rise to improvements of function prediction
(2005)
The growing number of uncharacterised sequences in public databases has turned the prediction of protein function into a challenging research field. Traditional annotation methods are often error-prone due to the small subset of proteins with experimentally verified function. Goal of this thesis was to analyse the function and evolution of protein domains in order to understand molecular processes in the cell. The focus was on signalling domains of little understood function, as well as on functional sites of protein domains in general. Glucosaminidases (GlcNAcases) represent key enzymes in signal transduction pathways. Together with glucosamine transferases, they serve as molecular switches, similar to kinases and phosphatases. Little was known about the molecular function and structure of the GlcNAcases. In this thesis, the GlcNAcases were identified as remote homologues of N-acetyltransferases. By comparing the homologous sequences, I was able to predict functional sites of the GlcNAcase family and to identify the GlcNAcases as the first family member of the acetyltransferase superfamily with a distinct catalytic mechanism, which is not involved in the transfer of acetyl groups. In a similar approach, the sensor domain of a plant hormone receptor was studied. I was able to predict putative ligand-binding sites by comparing evolutionary constraints in functionally diverged subfamilies. Most of the putative ligand-binding sites have been experimentally confirmed in the meantime. Due to the importance of enzymes involved in cellular signalling, it seems impossible to find substitutions of catalytic amino acids that turn them catalytically inactive. Nevertheless, by scanning catalytic positions of the protein tyrosine phosphatase families, I found many inactive domains among single domain and tandem domain phosphatases in metazoan proteomes. In addition, I found that inactive phosphatases are conserved throughout evolution, which led to the question about the function of these catalytically inactive phosphatase domains. An analysis of evolutionary site rates of amino acid substitutions revealed a cluster of conserved residues in the apparently redundant domain of tandem phosphatases. This putative regulatory center might be responsible for the experimentally verified dimerization of the active and inactive domain in order to control the catalytic activity of the active phosphatase domain. Moreover, I detected a subgroup of inactive phosphatases, which presumably functions in substrate recognition, based on different evolutionary site rates within the phosphatase family. The characterization of these new regulatory modules in the phosphatase family raised the question whether inactivation of enzymes is a more general evolutionary mechanism to enlarge signalling pathways and whether inactive domains are also found in other enzyme families. A large-scale analysis of substitutions at catalytic positions of enzymatic domains was performed in this work. I identified many domains with inactivating substitutions in various enzyme families. Signalling domains harbour a particular high occurrence of catalytically inactive domains indicating that these domains have evolved to modulate existing regulatory pathways. Furthermore, it was shown that inactivation of enzymes by single substitutions happened multiple times independently in evolution. The surprising variability of amino acids at catalytic positions was decisive for a subsequent analysis of the diversity of functional sites in general. Using functional residues extracted from structural complexes I could show that functional sites of protein domains do not only vary in their type of amino acid but also in their structural location within the domain. In the process of evolution, protein domains have arisen from duplication events and subsequently adapted to new binding partners and developed new functions, which is reflected in the high variability of functional sites. However, great differences exist between domain families. The analysis demonstrated that functional sites of nuclear domains are more conserved than functional sites of extracellular domains. Furthermore, the type of ligand influences the degree of conservation, for example ion binding sites are more conserved than peptide binding sites. The work presented in this thesis has led to the detection of functional sites in various protein domains involved in signalling pathways and it has resulted in insights into the molecular function of those domains. In addition, properties of functional sites of protein domains were revealed. This knowledge can be used in the future to improve the prediction of protein function and to identify functional sites of proteins.
Listeria monocytogenes ist ein fakultativ humanpathogenes Bakterium und aufgrund seiner Fähigkeit, in Zellen des Wirtes einzudringen und sich im Zytoplasma der befallenen Wirtszelle zu vermehren, ein attraktiver Träger, um heterolog exprimierte Antigene in den MHC-I- und -II-Präsentationsweg antigenpräsentierender Zellen (APC) einzuschleusen und so eine effektive zelluläre Immunreaktion zu erzeugen. Dabei hat die Art und Weise der Antigenexpression einen wesentlichen Einfluss auf die Erzeugung der antigenspezifischen Immunität. So konnte unter Verwendung extrazellulärer Trägerbakterien gezeigt werden, dass insbesondere die Verankerung von Antigenen auf der Zelloberfläche der Bakterien zu einer effektiven Induktion einer humoralen Immunantwort führt. Mit dem Ziel, mit einem derartigen Ansatz auch eine zelluläre Immunität zu erzeugen, wurde ein Plasmidsystem für die Expression von heterologen Proteinen in der Zellwand von L. monocytogenes entwickelt. Dabei gelang die Verankerung zahlreicher Proteine eukaryontischer wie auch prokaryontischer Herkunft über das LPXTG-Ankermotiv von Internalin A. Die so erzielte starke Expression in der Zellwand setzte aber sowohl die Fitness der Bakterien als auch deren Invasivität in vitro deutlich herab und verhinderte damit eine effektive MHC-I-Präsentation des verwendeten Modellantigens. Alternativ wurde L. monocytogenes bereits erfolgreich zur Übertragung von DNA-Vakzinen eingesetzt, um so auch die Synthese gegebenenfalls posttranslationell modifizierter Antigene in ihrer korrekten Konformation durch die infizierte Wirtszelle zu erzielen. Allerdings erfolgte die Expression des als Reporterprotein verwendeten EGFP insbesondere in APC sehr langsam und war von geringer Effizienz. Dabei konnte in der vorliegenden Arbeit erstmals gezeigt werden, dass nach bakterieller Übertragung von DNA-Vakzinen der Import der Plasmidmoleküle in den Kern insbesondere sich nicht teilender Zellen einen der wichtigsten Engpässe für eine möglichst frühzeitige und effektive Reportergenexpression darstellt. Einen Ausweg bietet die bakterielle Übertragung codierender mRNA, die unmittelbar nach der Freisetzung aus der Bakterienzelle im Zytoplasma der infizierten Wirtszelle zur Translation zu Verfügung steht. Dazu wurde das 5’-Ende der EGFP-codierenden Sequenz mit dem IRES-Element des Encephalomyocarditisvirus genetisch fusioniert. Um eine möglichst hohe Syntheserate zu erzielen und damit dem Abbau der mRNA in der Bakterienzelle entgegenzuwirken, erfolgte die Synthese der mRNA in L. monocytogenes mit Hilfe eines T7-RNA-Polymerase-basierten Transkriptionssystems. Im Gegensatz zur bakteriellen Übertragung von Plasmid-DNA konnte so bereits 4 h nach Infektion sowohl in epithelialen als auch in APC wie Makrophagen und humanen dendritischen Zellen eine deutliche EGFP-Expression nachgewiesen werden sowie bei Verwendung von Ovalbumin als Reporterprotein eine effektive MHC-I-Präsentation in vitro. Damit stellt die bakterielle Übertragung von mRNA einen vielversprechenden neuartigen Ansatz dar zur Erzeugung einer zellulären und gegebenenfalls auch humoralen Immunantwort gegen posttranslational modifizierte Antigene.
Honigbienen (Apis mellifera carnica) regulieren die Temperatur ihrer Brut in einem sehr engen Temperaturfenster, da vor allem die gedeckelte Brut sehr temperaturempfindlich reagiert (Groh et al. 2004). Die Thermoregulation ist nicht – wie lange angenommen – Beiprodukt von alltäglichen Arbeiten der Bienen im Brutbereich, sondern eine aktive und Energie- und Zeitaufwändige eigene Tätigkeit. Arbeiterinnen ziehen sich mit ihren Beinen an die Brutoberfläche, drücken ihren warmen Thorax auf die Brutdeckel und verharren so für einige Minuten um mit der eigenen Körperwärme die Brut zu temperieren (Bujok et al. 2002). Wie erwartet korrelierte die Thoraxtemperatur einer Arbeiterin mit der Frequenz der abdominalen Atembewegungen, bei sehr hohen Thoraxtemperaturen (über 40°C) erreichten die Bienen Atemfrequenzen von über 8Hz. Eine weitere Methode die Brut effektiv zu wärmen übten Bienen aus, die leere Zellen im gedeckelten Brutbereich besuchen (Kleinhenz et al. 2003). Arbeiterinnen gingen dabei bevorzugt in Zellen, die von möglichst vielen gedeckelten Zellen umgeben waren. Sowohl die Dauer der Zellbesuche, als auch die mittlere Thoraxtemperatur bei Ein- und Austritt der Zelle korrelierten mit der Anzahl der benachbarten Brutzellen – je mehr Brutzellen eine leere Zelle in ihrer direkten Nachbarschaft hatte umso länger dauerte der Besuch einer Biene und umso höher ist die Ein- bzw. Austrittstemperatur der Biene. Mindestes 48 Stunden alte Bienen unterschieden sich signifikant in ihrem Wärmeverhalten von jüngeren Bienen. Tote gedeckelte Brut wurde in manchen Fällen über viele Tage (durchgehend bis 10 Tage) gewärmt, sie unterschied sich in ihrer Temperatur nicht von unbehandelter gedeckelter Brut. In weiteren Versuchen lag die Bruttemperatur von toter Brut zwar unter der eines Kontrollbereiches, die Temperatur lag aber weiterhin im optimalen Bereich von 33,5 bis 35°C (Groh et al. 2004). In diesen Versuchen wurde die tote Brut vor dem Einsetzen in den Beobachtungsstock wieder auf 35°C erwärmt. Wachskegel in gedeckelten Zellen wurden erkannt und ausgeräumt. Aktive Signale, die von der Brut ausgehen scheinen also nicht notwendig für die effektive Bruttemperaturregulierung zu sein. Untersuchungen mittels Laser-Doppler-Vibrometrie zeigten auch keine Hinweise auf eine mechanische Kommunikation zwischen den Puppen und den Arbeiterinnen. Das Brutwärmen scheint eine Aktion zu sein, die von den Bienen nur in Gemeinschaft sinnvoll durchgeführt werden kann. In einigen Fällen kam es während der Puppenphase zu unerklärlichen Abfällen in der Bruttemperatur, die nur durch einen positiven Rückkopplungseffekt seitens der Arbeiterinnen erklärt werden kann. Beim Brutwärmen spielen die Antennen der Arbeiterinnen wahrscheinlich eine wichtige Rolle. Während sich die Bienen beim aktiven Brutwärmen den Brutdeckel annähern sind die Antennenspitzen immer auf die Brutdeckel gerichtet. Fehlen den Arbeiterinnen die Antennen, dann ist die Thermoregulation eingeschränkt oder unzureichend. Die Bruttemperatur korreliert mit der Anzahl der abgetrennten Antennensegmente, je mehr Antennensegmente fehlen, desto weniger gut wird die Temperatur im Brutbereich hoch und konstant gehalten. Zusätzlich scheint es eine Lateralität in der Antennenfunktion zu geben, wurde die rechte Antenne gekürzt wärmten die Bienen die Brut signifikant schlechter, als beim Kürzen der linken Antenne. Durch das Kürzen der Antennen änderte sich auch das Verhalten der Tiere: Kontrollbienen verharrten ruhig im Brutbereich, während Bienen mit gekürzten Antennen teilweise ähnlich warm waren, aber nicht mehr das oben beschriebene aktive Brutwärmeverhalten zeigten.
The vertebrate spinal cord is composed of billions of neurons and glia cells, which are formed in a highly coordinated manner during early neurogenesis. Specification of these cells at distinct positions along the dorsoventral (DV) axis of the developing spinal cord is controlled by a ventrally located signaling center, the medial floor plate (MFP). Currently, the origin and time frame of specification of this important organizer are not clear. During my PhD thesis, I have analyzed the function of the novel secreted growth factor Midkine-a (Mdka) in zebrafish. In higher vertebrates, mdk and the related factor pleiotrophin (ptn) are widely expressed during embryogenesis and are implicated in a variety of processes. The in-vivo function of both factors, however, is unclear, as knock-out mice show no embryonic phenotype. We have isolated two mdk co-orthologs, mdka and mdkb, and one single ptn gene in zebrafish. Molecular phylogenetic analyses have shown that these genes evolved after two large gene block duplications. In contrast to higher vertebrates, zebrafish mdk and ptn genes have undergone functional divergence, resulting in mostly non-redundant expression patterns and functions. I have shown by overexpression and knock-down analyses that Mdka is required for MFP formation during zebrafish neurulation. Unlike the previously known MFP inducing factors, mdka is not expressed within the embryonic shield or tailbud but is dynamically expressed in the paraxial mesoderm. I used epistatic and mutant analyses to show that Mdka acts independently from these factors. This indicates a novel mechanism of Mdka dependent MFP formation during zebrafish neurulation. To get insight into the signaling properties of zebrafish Mdka, the function of both Mdk proteins and the candidate receptor Anaplastic lymphoma kinase (Alk) have been compared. Knock-down of mdka and mdkb resulted in the same reduction of iridophores as in mutants deficient for Alk. This indicates that Alk could be a putative receptor of Mdks during zebrafish embryogenesis. In most vertebrate species a lateral floor plate (LFP) domain adjacent to the MFP has been defined. In higher vertebrates it has been shown that the LFP is located within the p3 domain, which forms V3 interneurons. It is unclear, how different cell types in this domain are organized during early embryogenesis. I have analyzed a novel homeobox gene in zebrafish, nkx2.2b, which is exclusively expressed in the LFP. Overexpression, mutant and inhibitor analyses showed that nkx2.2b is activated by Sonic hedgehog (Shh), but repressed by retinoids and the motoneuron-inducing factor Islet-1 (Isl1). I could show that in zebrafish LFP and p3 neuronal cells are located at the same level along the DV axis, but alternate along the anteroposterior (AP) axis. Moreover, these two different cell populations require different levels of HH signaling and nkx2.2 activities. This provides new insights into the structure of the vertebrate spinal cord and suggests a novel mechanism of neural patterning.
Flagellar motility and chemotaxis are essential virulence traits required for the ability of Helicobacter pylori to colonize the gastric mucosa. The flagellar regulatory network and the complex chemotaxis system of H. pylori are fundamentally different from other bacteria, despite many similarities. In H. pylori expression of the flagella is controlled by a complex regulatory cascade involving the two-component system FlgR-HP244, the sigma factors 54 and 28 and the anti-sigma 28 factor FlgM. Thus far, the input signal for histidine kinase HP244, which activates the transcriptional regulator FlgR, which triggers sigma factor 54-dependent transcription of the flagellar class 2 genes, is not known. Based on a yeast two-hybrid screen a highly significant protein-protein interaction between the H. pylori protein HP137 and both the histidine kinase HP244 and the flagellar hook protein HP908 (FlgE´) has been reported recently (Rain et al., 2001). So far, no function could be assigned to HP137. Interestingly, the interaction between HP137 and histidine kinase HP244 was observed in the characteristic block N sequence motif of the C-terminal ATP-binding kinase domain. In this work a potential role of HP137 in a feedback regulatory mechanism controlling the activity of histidine kinase HP244 in the flagellar regulation of H. pylori was investigated. Although the substitution of the gene encoding HP137 by a kanamycin cassette resulted in non-motile bacteria, the failure to restore motility by the reintroduction of hp137 in cis into the mutant strain, and the observation that HP137 has no significant effect on the activity of histidine kinase HP244 in vitro indicated that HP137 is not directly involved in flagellar regulation. Therefore, it was demonstrated that HP137 does not participate in the regulation of flagellar gene expression, neither in H. pylori nor in the closely related bacterium C. jejuni. Chemotactic signal transduction in H. pylori differs from the enterobacterial paradigm in several respects. In addition to a CheY response regulator protein (CheY1) H. pylori contains a CheY-like receiver domain (CheY2) which is C-terminally fused to the histidine kinase CheA. Furthermore, the genome of H. pylori encodes three CheV proteins consisting of an N-terminal CheW-like domain and a C-terminal receiver domain, while there are no orthologues of the chemotaxis genes cheB, cheR, and cheZ. To obtain insight into the mechanism controlling the chemotactic response of H. pylori the phosphotransfer reactions between the purified two-component signalling modules were investigated in vitro. Using in vitro phosphorylation assays it was shown that both H. pylori histidine kinases CheAY2 and CheA´ lacking the CheY-like domain (CheY2) act as ATP-dependent autokinases. Similar to other CheA proteins CheA´ shows a kinetic of phosphorylation represented by an exponential time course, while the kinetics of phosphorylation of CheAY2 is characterized by a short exponential time course followed by the hydrolysis of CheAY2~P. Therefore, it was demonstrated that the presence of the CheY2-like receiver domain influences the stability of the phosphorylated P1 domain of the CheA part of the bifunctional protein. Furthermore, it was proven that both CheY1 and CheY2 are phosphorylated by CheAY2 and CheA´~P and that the three CheV proteins mediate the dephosphorylation of CheA´~P, although with a clearly reduced efficiency as compared to CheY1 and CheY2. Moreover, CheA´ is capable of donating its phospho group to the CheY1 protein from C. jejuni and to CheY protein from E. coli. Retrophosphorylation experiments indicated that CheY1~P is able to transfer the phosphate group back to the HK CheAY2 and the receiver domain present in the bifunctional CheAY2 protein acts as a phosphate sink fine tuning the activity of the freely diffusible CheY1 protein, which is thought to interact with the flagellar motor. Hence, in this work evidence of a complex phosphorelay in the chemotaxis system was obtained which has similarities to other systems with multiple CheY proteins. The role of the CheV proteins remain unclear at the moment, but they might be engaged in a further fine regulation of the phosphate flow in this complex chemotaxis system and the independent function of the two domains CheA´ and CheY2 is not sufficient for normal chemotactic signalling in vivo.