TY - JOUR A1 - Scheer, Ulrich T1 - A novel type of chromatin organization in lampbrush chromosomes of Pleurodeles waltlii: visualization of clusters of tandemly repeated, very short transcriptional units N2 - A novel chromatin configuration is described in lampbrush chromosomes of Pleurodeles waltlii oocytes which is different from transcriptionally inactive chromatin as weil as from the various forms of transcribed chromatin hitherto described. This novel type of chromatin is not arranged in Christmas tree-Iike configurations of densely packed lateral ribonucleoprotein (RNP) fibriIs but is characterized by a periodic alternating pattern of thick and thin regions which occur in clusters 01 some 10,000 repeats. Each thickened unit with an average length of 45 nm contains two c10sely spaced particles, the putative RNA polymerases, and each thickened unit is separated from the next one by a beaded chromatin spacer with a length of about 80 nm. This chromatin spacer contains on average two particles of approximately 14 nm in diameter, assumed to be nucleosomes. The thickened regions are interpreted to represent short transcriptional units containing approximately 130 base pairs of DNA which are separated from each other by nontranscribed spacers of 240-400 base pairs of DNA. The possibility is discussed that these transcriptional units represent 5S rRNA or tRNA genes. KW - Lampbrush chromosomes KW - Amphibian oocytes KW - Transcription units KW - Electron microscopy Y1 - 1982 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-41087 ER - TY - JOUR A1 - Franke, Werner W. A1 - Kartenbeck, Jürgen A1 - Krien, S. A1 - VanderWoude, W. J. A1 - Scheer, Ulrich A1 - Morré, D. J. T1 - Inter- and intracisternal elements of the Golgi apparatus: A system of membrane-to-membrane cross-links N2 - Electron opaque cross-bridge structures span the inter- and intracisternal spaces and provide membrane-to-membrane connections between adjacent cisternae of dictyosomes of pollen tubes of Clivia and Lilium. Additionally, the classic intercisternal rods, characteristic of intercisternal regions near the maturing face of dictyosomes, are connected with the adjacent membranes through similar cross-bridge elements. We suggest that these structural links are responsible for maintaining the flattened appearance of the central parts of Golgi apparatus cisternae as well as for the coherence of cisternae within the stack. Observations on other plant (e.g. microsporocytes of Canna) and animal cells (e.g. rodent liver and hepatoma cells, newt spermatocytes) show that such an array of membrane cross-links is a universal feature of Golgi apparatus architecture. The cross-bridges appear as part of the complex "zone of exclusion" which surrounds dictyosomes, entire Golgi apparatus and Golgi apparatus equivalents in a variety of cell types. KW - Golgi apparatus KW - Membranes KW - Cross-bridges KW - Electron microscopy Y1 - 1972 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-39514 ER - TY - JOUR A1 - Scheer, Ulrich T1 - The ultrastructure of the nuclear envelope of amphibian ooctyes: IV. On the chemical nature of the nuclear pore complex material N2 - In order to investigate the chemical composition of the nuclear pore complexes isolated nuclei from mature Xenopus laevis oocytes were manually fractioned into nucleo· plasmic aggregates and the nuclear envelopes. The whole isolation procedure takes no more than 60- 90 sec, and the pore complexes of the isolated envelopes are well preserved as demonstrated by electron microscopy. Minor nucleoplasmic and cytoplasmic contaminations associated with the isolated nuclear envelopes were determined with electron microscopic morphometry and were found to be quantitatively negligible as far as their mass and nucleic acid content is concerned. The RNA content of the fractions was determined by direct phosphorus analysis after differential alkaline hydrolysis. Approximately 9% of the total nuclear RNA of the mature Xenopus egg was found to be attached to the nuclear envelope. The nonmembranous elements of one pore complex contain 0.41 X 10- 16 g RNA. This value agrees well with the content estimated from morphometric data. The RNA package density in the pore complexes (270 X 10- 15 g/fJ-3) is compared with the nucleolar, nucleoplasmic and cytoplasmic RNA concentration and is discussed in context with the importance of the pore complexes for the nucleo-cytoplasmic transport of RNA-containing macromolecules. Additionally, the results of the chemical analyses as well as of the 3H-actinomycin D autoradiography and of the nucleoprotein staining method of Bernhard (1969) speak against the occurence of considerable amounts of DNA in the nuclear pore complex structures. KW - Nuclear envelope KW - Amphibian oocytes KW - Nuclear pore complex KW - Chemical nature KW - Electron microscopy Y1 - 1972 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-39500 ER - TY - THES A1 - Elsner, Clara Dorothea T1 - Ultrastructural analysis of biogenesis and release of endothelial extracellular vesicles T1 - Ultrastrukturelle Analyse der Biogenese und Freisetzung von endothelialen extrazellulären Vesikeln N2 - Extracellular vesicle (EV)-mediated intercellular communication through exosomes, microvesicles (MVs) and apoptotic bodies has been shown to be implicated in various physiological as well as pathological processes such as the development and progression of atherosclerosis. While the cellular machinery controlling EV formation and composition has been studied extensively, little is known about the underlying morphological processes. This study focuses on a detailed ultrastructural analysis of the different steps of EV formation and release in Myocardial Endothelial (MyEnd) and Aortic Endothelial (AoEnd) cells cultured under serum starvation and inflammatory stimulation with TNF-α. Detailed morphological analyses were conducted applying and comparing different high- resolution light and electron microscopic methods. In this study, we could depict all steps of MV biogenesis named in literature. However, during the study of exosome biogenesis, we discovered a yet undescribed process: Instead of a direct fusion with the plasma membrane, multivesicular bodies were incorporated into a new distinct cellular compartment bound by fenestrated endothelium first. This may present a novel step in exosome biogenesis and warrants further study. Regarding the conditions of cell cultivation, we observed that the commonly used serum starvation causes MyEnd cells, but not AoEnd cells, to enter apoptosis after 48 hours. When preparing functional EV studies, we therefore recommend assessing the morphological condition of the serum-starved cells at different cultivation points first. When evaluating MV production, a statistical analysis showed that the more time AoEnd cells spent in cultivation under serum starvation, the higher the percentage of MV producing cells. However, additional TNF-α stimulation induced a significantly higher MV production than serum starvation alone. Lastly, our results show that TNF-α stimulation of AoEnd cells in vitro leads to the upregulation of CD44, an adhesion molecule critical in the early stages of atherosclerosis. CD44 was then depicted on the surface of generated MVs and exosomes. We conclude that under inflammatory conditions, EVs can mediate the transfer of CD44 from endothelial cells to target cells. This could be a novel mechanism by which MVs contribute to the development and progression of atherosclerotic disease and should be clarified by further studies. N2 - Extrazelluläre Vesikel (EV), darunter Exosomen, Mikrovesikel (MV) und apoptotische Körperchen, werden von fast allen Zellen des Körpers freigesetzt, transportieren zellspezifische Informationen und sind von großer Bedeutung in der Zell-Zell-Kommunikation. Sie spielen eine zentrale Rolle in verschiedensten physiologischen sowie pathologischen Vorgängen, wie etwa der Atherosklerose. Während die zellulären Mechanismen hinter der Entstehung und Komposition der EV bereits intensiv erforscht wurden, ist noch wenig über die zugrundeliegenden morphologischen Prozesse bekannt. Diese Arbeit präsentiert eine detaillierte ultrastrukturelle Analyse der Bildung und Freisetzung von EV in myokardialen (MyEnd) und aortalen Endothelzellen (AoEnd), die unter Serumentzug sowie inflammatorischer Stimulation mit TNF-α kultiviert wurden. Dazu wendeten wir verschiedene hochauflösende licht- und elektronenmikroskopische Techniken an. Wir konnten alle in der Literatur beschriebenen Schritte der MV-Biogenese darstellen. Bei der Untersuchung der exosomalen Biogenese entdeckten wir jedoch einen bisher unbekannten Prozess: Anstelle einer direkten Fusion der multivesikulären Körperchen mit der Plasmamembran, wurden diese zunächst in ein neues, von fenestriertem Endothel begrenztes, zelluläres Kompartiment integriert. Ferner stellten wir fest, dass der häufig durchgeführte Serumentzug während der Kultivierung bei MyEnd- – allerdings nicht AoEnd- – Zellen nach 48 Stunden zur Apoptose führte. Daher empfehlen wir, bei funktionellen Studien von EV zunächst eine morphologische Untersuchung der unter Serumentzug kultivierten Zellen zu verschiedenen Zeitpunkten durchzuführen. Eine statistische Analyse der MV-Produktion zeigte, dass die Zellen umso mehr MV produzierten, je länger sie sich unter Serumentzug befanden. Jedoch induzierte eine zusätzliche Stimulation mit TNF-α eine signifikant höhere MV-Produktion als der alleinige Serumentzug. Wir konnten zeigen, dass eine TNF-α Stimulation von AoEnd Zellen in vitro zu einer vermehrten Expression von CD44 führte – einem vor allem in der Frühphase der Atherosklerose bedeutendem Adhäsionsmolekül. CD44 konnte ebenso auf der Oberfläche von produzierten MV und Exosomen nachgewiesen werden. Wir schließen daraus, dass MV unter inflammatorischen Bedingungen den Transfer von CD44 von Endothelzellen zu Zielzellen vermitteln und so zur Entstehung und Progression von Atherosklerose beitragen können. KW - Vesikel KW - Exosom KW - Endothelzelle KW - Zellkommunikation KW - Atherosklerose KW - Extracellular Vesicles KW - Microvesicles KW - Exosomes KW - Cell-cell communication KW - Electron microscopy Y1 - 2022 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-288526 ER -