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Lesion of the rat entorhinal cortex denervates the outer molecular layer of the fascia dentata followed by layer-specific axonal sprouting of uninjured fibers in the denervated zone. One of the candidate molecules regulating the laminar-specific sprouting response in the outer molecular layer is the transmembrane chondroitin sulfate proteoglycan NG2. NG2 is found in glial scars and has been suggested to impede axonal regeneration following injury of the spinal cord. The present study adressed the question whether NG2 could also regulate axonal growth in denervated areas of the brain. Therefore, (1) changes in NG2 mRNA and NG2 protein levels, (2) the cellular and the extracellular localisation of the molecule, (3) the identity of NG2 expressing cells, and (4) the generation of NG2-positive cells were studied in the rat fascia dentata before and following entorhinal deafferentation. Laser microdissection was employed to selectively harvest the denervated molecular layer and combined with quantitative reverse transcription-PCR to measure changes in NG2 mRNA amount (6h, 12h, 2d, 4d, 7d post lesion). The study revealed increases of NG2 mRNA at day 2 (2.5-fold) and day 4 (2-fold) post lesion. Immunocytochemistry was used to detect changes in NG2 protein distribution (1d, 4d, 7d, 10d, 14d, 30d, 6 months post lesion). NG2 staining was increased in the denervated outer molecular layer at 1 day post lesion, reached a maximum at 10 days post lesion, and returned to control levels within 6 month. Interestingly, the accumulation of NG2 protein was strongly restricted to the denervated outer molecular layer forming a border to the unaffected inner molecular layer. Using electron microscopy, NG2-immunoprecipitate was localized not only on glial surfaces and in the extracellular matrix but also in the vicinity of neuronal profiles indicating that NG2 is secreted following denervation. Double-labelings of NG2-immunopositive cells with markers for astrocytes, microglia/macrophages, and oligodendrocytes suggested that NG2-cells are a distinct glial subpopulation before and after entorhinal deafferentation. Bromodeoxyuridine-labeling revealed that some of the NG2-positive cells are postlesional generated. Taken together, the data revealed a layer-specific upregulation of NG2 in the denervated outer molecular layer of the fascia dentata that coincides with the sprouting response of uninjured fibers. This suggests that NG2 could regulate lesion-induced axonal growth in denervated areas of the brain.
Here I analyse 23 populations of D. galeata, a large-lake cladoceran, distributed mainly across the Palaearctic. I detected high levels of clonal diversity and population differentiation using variation at six microsatellite loci across Europe. Most populations were characterised by deviations from H-W equilibrium and significant heterozygote deficiencies. Observed heterozygote deficiencies might be a consequence of simultaneous hatching of individuals produced during different times of the year or of the coexistence of ecologically and genetically differentiated subpopulations. A significant isolation by distance was only found over large geographic distances (> 700 km). This pattern is mainly due to the high genetic differentiation among neighbouring populations. My results suggest that historic populations of Daphnia were once interconnected by gene flow but current populations are now largely isolated. Thus local ecological conditions which determine the level of biparental sexual reproduction and local adaptation are the main factors mediating population structure of D. galeata. The population genetic structure and diversity in D. galeata was investigated at a European scale using six microsatellite loci and 12S rDNA sequence data to infer and compare historical and contemporary patterns of gene flow. D. galeata has the potential for long-distance dispersal via ephippial resting eggs by wind and other dispersing vectors (waterfowl), but shows in general strong population differentiation even among neighbouring populations. A total of 427 individuals were analysed for microsatellite and 85 individuals for mitochondrial (mtDNA) sequence data from 12 populations across Europe. I detected genetic differentiation among populations across Europe and locations within sampling regions for both genetic marker systems (average values: mtDNA FST = 0.574; microsatellite FST = 0.389), resulting in a lack of isolation by distance. Furthermore, several microsatellite alleles and one haplotype were shared across populations. Partitioning of molecular variance was inconsistant for both marker systems. Microsatellite variation was higher within than among populations, whereas mtDNA data yielded an inverse pattern. Relative high levels of nuclear DNA diversity were found across Europe. The amount of mitochondrial diversity was low in Spain, Hungary and Denmark. Gene flow analysis at a European scale did not reveal typical pattern of population recolonization in the light of postglacial colonization hypotheses. Populations, which recently experienced an expansion or population-bottleneck were observed both in middle and northern Europe. Since these populations revealed high genetic diversity in both marker systems, I suggest these areas to represent postglacial zones of secondary contact among divergent lineages of D. galeata. In order to reveal the relationship between population genetic structure of D. galeata and the relative contribution of environmental factors, I used a statistical framework based on canonical correspondence analysis. Although I detected no single ecological gradient mediating the genetic differentiation in either lake regions, it is noteworthy that the same ecological factors were significantly correlated with intra- and interspecific genetic variation of D. galeata. For example, I found a relationship between genetic variation of D. galeata and differentiation with higher and lower trophic levels (phytoplankton, submerged macrophytes and fish) and a relationship between clonal variation and species diversity within Cladocera. Variance partitioning had only a minor contribution of each environmental category (abiotic, biomass/density and diversity) to genetic diversity of D. galeata, while the largest proportion of variation was explained by shared components. My work illustrates the important role of ecological differentiation and adaptation in structuring genetic variation, and it highlights the need for approaches incorporating a landscape context for population divergence.
The mammalian retina contains around 30 morphological varieties of amacrine cell types. These interneurons receive excitatory glutamatergic input from bipolar cells and provide GABA- and glycinergic inhibition to other cells in the retina. Amacrine cells exhibit widely varying light evoked responses, in large part defined by their presynaptic partners. We wondered whether amacrine functional diversity is based on a differential expression of glutamate receptors among cell populations and types. In whole cell patch-clamp experiments on mouse retinal slices, we used selective agonists and antagonists to discriminate responses mediated by NMDA/ non-NMDA (NBQX) and AMPA/ KA receptors (cyclothiazide, GYKI 52466, GYKI 53655, SYM 2081). We sampled a large variety of individual cell types, which were classified by their dendritic field size into either narrow-field or wide-field cells after filling with Lucifer yellow or neurobiotin. In addition, we used transgenic GlyT2-EGFP mice, whose glycinergic neurons express EGFP. This allowed us to classify amacrines on basis of their neurotransmitter into either glycinergic or GABAergic cells. All cells (n = 300) had good responses to non-NMDA agonists. Specific AMPA receptor responses could be obtained from almost all cells recorded: 94% of the AII (n = 17), 87% of the narrow-field (n = 45), 81% of the wide-field (n = 21), 85% of the glycinergic (n = 20) and 78% of the GABAergic cells (n = 9). KA receptor selective drugs were also effective on the majority of the AII (79%, n = 14), narrow-field (93%, n = 43), wide-field (85%, n = 26), glycinergic (94%, n = 16) and GABAergic amacrine cells (100%, n = 6). Among the cells tested for the two receptors (n = 65), we encountered both exclusive expression of AMPA or KA receptors and co-expression of the two types. Most narrow-field (70%, n = 27), glycinergic (81%, n = 16) and GABAergic cells (67%, n = 6) were found to have both AMPA and KA receptors. In contrast, only less than half of the wide-field cells (43%, n = 14) were found to co-express AMPA and KA receptors, most of them expressing exclusively AMPA (36%) or KA receptors (21%). We could elicit small NMDA responses from most of the wide-field (75%, n = 13) and GABAergic cells (67%, n = 3), whereas only 47% of the narrow-field (n = 15), 14% of the AII (n = 22) and no glycinergic cell (n = 2) reacted to NMDA. Abstract 83 Our data suggest that AMPA, KA and NMDA receptors are differentially expressed among different types of amacrine cells rather than among populations with different neurotransmitters or different dendritic coverage of the retina. Selective expression of kinetically different glutamate receptors among amacrine types may be involved in generating transient and sustained inhibitory pathways in the retina. Since AMPA and KA receptors are not generally clustered at the same postsynaptic sites, a single amacrine cell expressing both AMPA and KA receptors may provide inhibition with different temporal characteristics to individual synaptic partners.
Life of Varroa destructor, Anderson and Trueman, an ectoparasitic mite of honeybees, is divided into a reproductive phase in the bee brood and a phoretic phase during which the mite is attached to the adult bee. Phoretic mites leave the colony with workers involved in foraging tasks. Little information is available on the mortality of mites outside the colony. Mites may or not return to the colony as a result of death of the infested foragers, host change by drifting of foragers, or removal of mites outside the colony. That mites do not return to the colony was indicated by substantially higher infestation of outflying workers compared to the infestation of returning workers (Kutschker, 1999). The main objective of the study was to provide information whether V. destructor influences flight behaviour of foragers and consequently returning frequency of foragers to the colony. I first repeated the experiment of Kutschker (1999) examining the infestation of outflying and returning workers. Further, I registered flight duration of foragers using a video method. In this experiment I compared also the infestation and flight duration of bees of different genetic origin, Carnica from Oberursel and bees from Primorsky region. I investigated returning time of workers, returning frequency until evening, drifting to other colonies and orientation toward the nest entrance in the experiments in which workers were released in close vicinity of the colony. At last, I measured the loss of foragers in relation to colony infestation using a Bee Scan. Results from this study, listed below, showed considerable influence of V. destructor on flight behavior of foragers translating into loss of mites. Loss of mites with foragers add substantial component to mite mortality and was underestimated in previous studies. Such loss might be viewed as a mechanism of resistance against V. destructor. a) The mean infestation of outflying workers (0.019±0.018) was twice as the mean infestation of returning workers (0.009±0.018). The difference in the infestation between outflying and returning workers was more marked in highly infested colonies. b) Investigation of individually tagged workers by use of a two camera video recording device showed significantly higher infestation of outflying workers compared to returning workers. Mites were lost by the non returning of infested foragers (22%) and by loss of mites from foragers that returned to the colony without the mite (20%). A small portion of mites (1.8%) was gained. Loss of mites significantly exceeded mite gain. c) The flight duration of infested workers determined by using the same two camera video system was significantly higher in infested compared to uninfested workers of the same age that flew closest at time. The median flight duration of infested workers was 1.7 higher (214s) than the median duration of unifested workers (128s). d) Infested workers took 2.3 times longer to return to the colony than uninfested workers of the same age when released from the same locations, closest at time. The returning time increased with the distance of release. In a group of bees released simultaneously the infestation was higher in bees returning later and in those that did not return in the observation period of 15 min. e) Released workers did not return to the colony 1.5 more frequently than uninfested workers in evening. The difference in returning was significant for locations of 20 and 50m from the colony. No difference in returning between infested and uninfested workers were observed for the most distant location of 400m. f) No significant difference was found in returning time and/or in the returning frequency until evening between workers artificially infested overnight and naturally infested workers. Artificially infested workers returned later and less frequently than a control group indicating rapid influence of V. destructor on flight behavior of foragers. g) The orientation ability of infested workers toward the nest entrance was impaired. Infested workers compared to uninfested workers twice as often approached a dummy entrance before finding the nest entrance. h) No significant differences were found in drifting between infested and uninfested workers. Drifting in the neighboring nucleus colony occurred in about 1% occasions after release of marked workers. Similarly, more infested, but not significantly more infested workers (2.6%) entered a different colored hive than the same colored hive (1.9%). However, the number of drifting bees were to low to make results conclusive. i) The comparison between Carnica and Primorsky workers revealed higher infestation in Carnica compared to Primorsky. Further, Primorsky workers lost more mites during foraging due to mite loss from foragers and non returning of infested workers. No significant differences in flight duration were observed between the two bee stocks. j) Loss of foragers, as determined by the Bee Scan counts of outflying and returning foragers, and the infestation of outflying bees increased significantly over a period of 70 days. A colony with 7.7. higher infestation of outflying foragers lost 2.2. time more bees per flight per day compared to a low infested colony. k) The estimates of mite loss with foragers from mite population per day up to 3.1% exceeds approximately mite mortality of 1% within the colony as represented by counting dead mites on bottom board inserts.
In contrast to the class A heat stress transcription factors (Hsfs) of plants, a considerable number of Hsfs assigned to classes B and C have no evident function as transcription activators on their own. In the course of my PhD work I showed that tomato HsfB1, a heat stress induced member of class B Hsf family, is a novel type of transcriptional coactivator in plants. Together with class A Hsfs, e.g. tomato HsfA1, it plays an important role in efficient transcrition initiation during heat stress by forming a type of enhanceosome on fragments of Hsp promoter. Characterization of promoter architecture of hsp promoters led to the identification of novel, complex heat stress element (HSE) clusters, which are required for optimal synergistic interactions of HsfA1 and HsfB1. In addition, HsfB1 showed synergistic activation of the expression of a subset of viral and house keeping promoters. CaMV35S promoter, the most widely expressed constitutive promoter turned out to be the the most interesting candidate to study this effect in detail. Because, for most house-keeping promoters tested during this study, the activators responsible for constitutive expression are not known, but in case of CaMV35S promoter they are quite well known (the bZip proteins, TGA1/2). These proteins belong to the acidic activators, similar to class A Hsfs. Actually, on heat stress inducible promoters HsfA1 or other class A Hsfs are the synergistic partners of HsfB1, whereas on house-keeping or viral promoters, HsfB1 shows synergistic transcriptional activation in cooperation with the promoter specific acidic activators, e.g. with TGA proteins on 35S promoter. In agreement with this the binding sites for HsfB1 were identified in both house-keeping and 35S promoter. It has been suggested during this study that HsfB1 acts in the maintenance of transcription of a sub-set of house-keeping and viral genes during heat stress. The coactivator function of HsfB1 depends on a single lysine residue in the GRGK motif in its CTD. Since, this motif is highly conserved among histones as the acetylation motif, especially in histones H2A and H4,. It was suggested that the GRGK motif acts as a recruitment motif, and together with the other acidic activator is responsible for corecruitment of a histone acetyl transferase (HAT). So, the effect of mammalian CBP (a well known HAT) and its plant orthologs (HAC1) was tested on the stimulation of synergistic reporter gene activation obtained with HsfA1 and HsfB1. Both in plant and mammalian cells, CBP/HAC1 further stimulated the HsfA1/B1 synergistic effect. Corecruitment of HAC1 was proven by in vitro pull down assays, where the NTD of HAC1 interacted specifically both with HsfA1 and HsfB1. Formation of a ternary complex between HsfA1, HsfB1 and CBP/HAC1 was shown via coimmunoprecipitation and electrophoretic mobility shift assays (EMSA). In conclusion, the work presented in my thesis presents a new model for transcriptional regulation during an ongoing heat stress.
In an attempt to search for potential candidate molecules involved in the pathogenesis of endometriosis, a novel 2910 bp cDNA encoding a putative 411 amino acid protein, shrew-1 was discovered. By computational analysis it was predicted to be an integral membrane protein with an outside-in transmembrane domain but no homology with any known protein or domain could be identified. Antibodies raised against the putative open-reading frame peptide of shrew-1 labelled a protein of ca. 48 kDa in extracts of shrew-1 mRNA positive tissues and also detected ectopically expressed shrew-1. In the course of my PhD work, I confirmed the prediction that shrew-1 is indeed a transmembrane protein, by expressing epitope-tagged shrew-1 in epithelial cells and analysing the transfected cells by surface biotinylation and immunoblots. Additionally, I could show that shrew-1 is able to target to E-cadherin-mediated adherens junctions and interacts with the E-cadherin-catenin complex in polarised MCF7 and MDCK cells, but not with the N-cadherin-catenin complex in non-polarised epithelial cells. A direct interaction of shrew-1 with beta-catenin could be shown in an in vitro pull-down assay. From this data, it could be assumed that shrew-1 might play a role in the function and/or regulation of the dynamics of E-cadherin-mediated junctional complexes. In the next part of my thesis, I showed that stable overexpression of shrew-1 in normal MDCK cells. causes changes in morphology of the cells and turns them invasive. Furthermore, transcription by ²-catenin was activated in these MDCK cells stably overexpressing shrew-1. It was probably the imbalance of shrew-1 protein at the adherens junctions that led to the misregulation of adherens junctions associated proteins, i.e. E-cadherin and beta-catenin. Caveolin-1 is another integral membrane protein that forms complexes with Ecadherin- beta-catenin complexes and also plays a role in the endocytosis of E-cadherin during junctional disruption. By immunofluorescence and biochemical studies, caveolin-1 was identified as another interacting partner of shrew-1. However, the functional relevance of this interaction is still not clear. In conclusion, it can be said that shrew-1 interacts with the key players of invasion and metastasis, E-cadherin and caveolin-1, suggesting its possible role in these processes and making it an interesting candidate to unravel other unknown mechanisms involved in the complex process of invasion.
A gene trap strategy was used to identify genes induced in hematopoietic cells undergoing apoptosis by growth factor withdrawal. IL-3 dependent survival of hematopoietic cells relies on a delicate balance between proliferation and apoptosis that is controlled by the availability of cytokines (Thompson, 1995; Iijima et al., 2002). From our previous results of gene trap assay, we postulated that transcriptionally activated antagonistic genes against apoptosis might actually block or delay cell death (Wempe et al., 2001) causing cells to have carcinogenic behavior. The analysis attempted to better understand the outcome of a death program following IL-3 deprivation and to identify those survival genes whose expression is affected by time dependent manner. As described in the chapter 4, there would be two major conclusions evident from the three separate experiments (Genetrap, Atlas cDNA array and Affymetrix chips): Firstly 56% of trapped genes, that are up-regulated by IL-3 withdrawal (28 of 50), are directly related to cell death or survival. Secondly, unlike most array technologies, gene trapping only selects for the transiently induced genes that is independent of pre-existing steady state mRNA levels. In regarding correlations of the genes with potential carcinogenesis, the pre-existing mRNA makes difficult to describe the unique characteristics of deregulated tumor tissue genes. For a joint project with Schering (Schering AG, Berlin), the genes of our GTSTs were examined. The first screen with custom array was used to look for whether the survival genes of our GTSTs are involved in various cancer cell lines, whilst the second screen with Matched Tumor/Normal Array was used to characterize if the selected seven genes (ERK3, Plekha2, KIAA1140, PI4P5Ka/g, KIAA0740, KIAA1036 and PEST domains) are transformation-related genes or not in different tumor tissues. Twenty-six genes were identified as either induced or repressed in one or more cell lines. Genetic information is expressed in complex and ever changing patterns throughout a life span of cells. A description of these patterns and how they relate to the tissue specific cancer is crucial for our understanding of the network of genetic interactions that underlie the processes of normal development, disease and evolution. The development of cancer and its progression is clearly a multiplex phenotype, as a function of time, involving dozens of primary genes and hundreds of secondary modifier genes. There would be a major conclusion evident from the three separate experiments (Genetrap, Affymetrix mouse chip and Matched Tumor/Normal Array): ERK3 could play a significant role in breast, stomach and uterus carcinogenesis with tissue specific regulations. It is clear that ERK3 is obvious putative survival gene in these tumor tissues. Especially, in breast tumors, seven times up-regulation was considerable and the activation of ERK3 could be a feature of breast tumors. My results imply that the unique deregulation of ERK3 is perhaps the major consequence of possible transformation of normal cells into malignant cancer cells, even though further analysis remains to be determined whether an alterated activity of associated survival genes is primarily responsible for a carcinogenesis. However unlike all the other known MAP Kinases, no stimuli and no nuclear substrates of ERK3 is reported. Therefore, it will be necessary first to determine the spectrum of substrates and to identify the proximal effectors for the ERK3 in breast carcinoma cells.
Zahnwale sind die einzige Säugetiergruppe, die umfassend an ein Leben im Wasser angepasst ist und dabei ein aktives Sonarsystem zur Orientierung nutzt. Wahrscheinlich produzieren alle Zahnwalarten sonische oder ultrasonische Klicklaute, deren Echos die Tiere zu einem drei-dimensionalen "akustischen Bild" zusammensetzen. Im Gegensatz zu den meisten anderen Säugetieren produzieren Zahnwale diese Laute im Nasen-Komplex durch einen pneumatisch betriebenen Mechanismus. Jedoch spielt auch der Kehlkopf dabei eine wichtige Rolle, indem er den nötigen Luftdruck in der Nase erzeugt. Die Ergebnisse werden in Bezug auf die physikalischen Voraussetzungen eines Bio-Sonars in einer aquatischen Umwelt interpretiert. Um die morphologischen Eigenschaften (Struktur, Form, Topographie) der Organe im Kopf verschiedener Zahnwalarten vollständig zu erfassen, wurden diese mittels Computertomographie und Magnetresonanztomographie gescannt. Daraufhin wurden die Köpfe makroskopisch präpariert und histologische Schnitte von Gewebeproben angefertigt. Schließlich wurden die Ergebnisse durch digitale dreidimensionale Rekonstruktionen vervollständigt. Diese Studie basiert zum größten Teil auf der Untersuchung von Schweinswalen (Phocoena phocoena) und Pottwalen (Physeter macrocephalus). Zum Vergleich wurden fetale und postnatale Individuen anderer Zahnwalarten herangezogen wie Delphinartige (Delphinus delphis, Stenella attenuata, Tursiops truncatus), Flussdelphinartige (Pontoporia blainvillei, Inia geoffrensis) und der Zwergpottwal (Kogia breviceps). Im Allgemeinen konnte durch die morphologischen Daten dieser Studie die einheitliche "phonic lips-Hypothese der Schallproduktion bei Zahnwalen, wie sie von Cranford, Amundin und Norris [J. Morphol. 228 (1996): 223-285] aufgestellt wurde, bestätigt werden. Diese Hypothese beschreibt eine ventilartige Struktur in der Nasenpassage, den sogenannten "monkey lips/dorsal bursae complex" (MLDB) als Schallgenerator. Der pneumatische Mechanismus lässt die beiden Hälften des MLDB aufeinanderschlagen und erzeugt damit die initiale Schallschwingung im Gewebe ("phonic lips"). Diese Vibration wird über die Melone, einen großen Fettkörper in der vorderen Nasenregion der Zahnwale, fokussiert und in das umgebende Wasser übertragen. Die akzessorischen Nasensäcke und spezielle Schädel- und Bindegewebestrukturen können zu der Fokussierung beitragen. Obwohl die Echolotsignale der Schweinswale sehr spezialisiert zu sein scheinen, weisen die Übereinstimmungen in der Topographie und in der Form der Nasenstrukturen im Vergleich zu Delphinen und Flussdelphinartigen (Pontoporia und Inia) auf eine ganz ähnliche Funktion der Nase bezüglich der Produktion und Emission von Echolotschall hin. Allerdings gibt es einige anatomische Besonderheiten im Nasenkomplex des Schweinswals, welche die besondere Pulsstruktur der Sonarsignale erklären könnte. Diese werden in der Dissertation diskutiert. Bei einem Vergleich der Nasenmorphologie der Pottwale einerseits und der nicht-pottwalartigen Zahnwale andererseits fällt vor allem der Grad der Asymmetrie ins Auge. Im Gegensatz zu dem oben für Delphine und Schweinswale beschrieben Mechanismus betreiben Pottwale die Schallproduktion an den "monkey lips" mit Luft, die im rechten Nasengang unter Druck gesetzt wird (und nicht im nasopharyngealen Raum). Zudem könnte durch Änderung des Luftvolumens im rechten Nasengang die Schalltransmission zwischen den Fettkörpern, und somit die Schallemission, kontrolliert werden. In diesem theoretischen Szenario fungiert der breite rechte Nasengang als eine Art "akustische Schranke", welche zwischen zwei verschiedenen Modi der Klickproduktion wechselt: Der erste Modus mit luftgefülltem Nasengang führt zur Produktion der Kommunikationsklicks ("coda clicks") und der zweite Modus zur Aussendung von Echolotklicks, wenn der Nasengang kollabiert ist. Somit scheinen die zentrale Position und die nahezu horizontale Orientierung des rechten Nasengangs im Kopf der Pottwale als Schnittstelle (Schranke) zwischen den beiden großen Fettkörpern mit dem Mechanismus der Schallproduktion bei veränderten Luftvolumina korreliert zu sein. Die hier beschriebenen und andere Ergebnisse dieser Dissertation deuten darauf hin, dass die Gestalt und das Ausmaß der Nasenasymmetrie nicht mit der systematischen Zugehörigkeit der jeweiligen Art korrelieren, sondern durch den jeweiligen Typus des Sonarsystems als Ausdruck einer bestimmten ökologischen Anpassung bedingt sind. Bei Zahnwalen ist der Kehlkopf charakterisiert durch eine rostrale Verlängerung des Kehldeckels und der beiden Stellknorpel, die ein gänseschnabelartiges Rohr bilden, das von einem starken Sphinktermuskel umrundet und dabei in Position gehalten wird. Auf diese Weise ist das Atemrohr vollständig vom Digestionstrakt getrennt. Aus anatomischer Sicht ist es wahrscheinlich, dass die Schallerzeugung bei Zahnwalen durch eine Kolbenbewegung des Kehlkopfes in Richtung der Choanen zustande kommt, wodurch der Luftdruck im Nasenbereich erzeugt wird. Die Kontraktion des Sphinktermuskels als einem muskulösen Schlauch erzeugt wahrscheinlich die größte Kraft für diese Kolbenbewegung. Jedoch dürften die Muskelgruppen, die den Kehlkopf und das Zungenbein am Unterkiefer und an der Schädelbasis aufhängen, signifikant zur Druckerhöhung beitragen.
In the present study the cryo-immunogold technique was used and optimized for investigating the ultrastructure and immunolabeling of synaptic proteins. It is evidently a suitable method for the localization of membrane proteins since the antigens are not treated with any chemical denaturation before immunolabeling except for the fixation and since the antigens are directly exposed to the surface of the cryo-ultrasections. The v-SNARE VAMP II and the vesicle-associated proteins SV2 and Rab3A were detected extensively at small vesicles in the mossy fiber terminals. The t-SNARE SNAP-25, and N-type and P/Q type Ca2+ channels were allocated to the plasma membrane both at the active zone and outside the active zone. SNAP-25 and N-type Ca2+ channels appeared also at synaptic vesicles. A significantly increased immunolabeling of VAMP II, SV2, Rab3A, SNAP-25 and N-type Ca2+ channels was found at the active zones of fast synapses, indicating a concentration of these proteins at sites of exocytosis. The widespread distribution of the t-SNARE SNAP-25 at the axonal plasma membrane reveals that membrane-targeting specificity cannot be determined solely by v/t-SNARE interactions. Additional control components are required to assure the docking and exocytosis of the synaptic vesicles at active zones. The novel protein Bassoon was only found at active zones of central synapses and showed the highest specific labeling among all proteins investigated. Its labeling pattern implies an association of Bassoon with the presynaptic dense projections, the structural guide for vesicle exocytosis. The involvement of Bassoon in the organization of the neurotransmitter release site suggests that Bassoon may play an important role in determining the specificity of vesicle docking and fusion. In the neurosecretory endings of neurohypophysis the synaptic proteins VAMP II, SNAP- 25, SV2, Rab3A, and the N-type Ca2+ channels showed a preferential labeling over microvesicles. Moreover, the immunolabeling intensity of these proteins over microvesicles corresponded closely to that over synaptic vesicles. This suggests that these synaptic proteins share an identical association with synaptic vesicle and microvesicles. A significant labeling of SNAP-25, the N-type Ca2+ channels and VAMP II was also detected at the plasma membrane near the clustered microvesicles, indicating the competence of microvesicles for docking and exocytosis along the plasma membrane in the absence of active zones. No significant labeling of VAMP II, SNAP-25, SV2 and N-type Ca2+ channel was observed at the membrane of neurosecretory granules. This is in agreement with the notion that synaptic vesicles and microvesicles possess regulatory mechanisms for exocytosis different from those of granules. In contrast, a/ß-SNAP and NSF were found on the granules, and Rab3A and the P/Q-type Ca2+ channels on granules in a subset of terminals. Rab3A is associated specifically with the oxytocin-containing granule population. Interestingly, some plasma membrane proteins, such as SNAP-25 and even N-type Ca2+ channels and P/Q-type Ca2+ channels, were observed not only at the plasma membrane but also at the vesicular organelles. This suggests that these vesicular organelles may be involved in transporting newly synthesized proteins from the soma to the plasma membrane of the terminal. Furthermore, the vesicular pool of the Ca2+ channels may serve in the stimulationinduced translocation into the plasma membrane when required. Using the conventional preembedding method with Epon and the post-embedding method with LR Gold, VAMP II was localized at vesicular organelles of varying size and on horseradish peroxidase filled endocytic organelles in cultured astrocytes, with and without stimulation in the presence of the horseradish peroxidase. This indicates that VAMP II is involved in the cycle of vesicular exocytosis and endocytosis in astrocytes. U373 cells are capable of expressing all three members of the synaptic SNARE complex (v-SNARE VAMP II, t-SNARE syntaxin I and SNAP25). This indicates the competence of U373 to carry out regulated exocytosis by means of the classical SNARE mechanism. In addition, the ubiquitous v-SNARE cellubrevin and the endosome-associated small GTPbinding protein Rab5 could be expressed in U373 cells. All recombinant synaptic proteins investigated in U373 cells revealed a punctuate cellular distribution under the fluorescence microscope, suggesting that they are mainly associated with intracellular compartments. The cryo-electron microscopy provided direct evidence for the association of all expressed proteins with electron-lucent vesicular organelles. It further supports the potential of U373 MG cells to release low molecular weight messengers by a regulated exocytosis mechanism. In addition, myc-VAMP II was found on dispersed granules. Probably, VAMP II also participates in the exocytosis event of granules in U373 cells. Gold labeling for the two presumptive t-SNAREs syntaxin I and SNAP-25 in U373 cells was confined to the vesicular organelles. At the ultrastructural level no significant labeling was identified at the plasma membrane. The high level of colocalization of the two SNARE proteins VAMP II and syntaxin I in the cell body and in cell processes suggests that the two proteins are mostly sorted into identical vesicular organelles. A partial colocalization of VAMP II and cellubrevin as well as of VAMP II and Rab5 was observed under the fluorescence microscope. At the ultrastructural level, a colocalization of VAMP II and cellubrevin as well as of VAMP II and Rab5 was found on some clustered vesicles. The partial colocalization of VAMP II and cellubrevin implies that they similarly function as v-SNAREs. The partial colocalization of Rab5 with VAMP II in U373 cells suggests that the endosomal protein Rab5 is associated with VAMP II-containing organelles during some stages of their life cycle.