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A unique relationship between switching, mating and biofilm formation in the human pathogen Candida albicansYi, Song 01 July 2009 (has links)
Candida albicans is the most prevalent human fungal pathogen. The research described in this thesis has focused on the identification and characterization of the regulatory pathways in this pathogen controlling white-opaque switching, mating and biofilm formation as well as the relationship between them. White-opaque switching and mating in C. albicans are under the repression of the a1-α2 complex. Based on this, a chromatin immunoprecipitation-microarray analysis of the a1-α2 target genes was conducted to search for the master switch locus. The result identified TOS9 (WOR1) as a master regulator gene, and overexpression of TOS9 resulted in a switch en masse from white to opaque. In 2006, a novel form of communication was demonstrated between white and opaque cells in C. albicans. It was shown that minority opaque cells through the release of pheromone signaled majority white cells of the opposite mating type to become cohesive, adhesive and form enhanced biofilms. These biofilms in turn facilitated opaque cell chemotropism required for opaque cell mating. To identify the pathway regulating the white cell pheromone response, deletion mutants were generated for select genes mediating the opaque cell mating response. It was demonstrated that the pathways regulating the white and opaque cell responses to the same pheromone share the same upstream components, including receptors, heterotrimeric G protein, and mitogen-activated protein kinase cascade, but they use different downstream transcription factors that regulate the expression of genes specific to the alternative responses. This configuration, although found in higher, multicellular systems, is uncommon in fungi and suggests that it may be an antecedent to multicellularity in higher eukaryotes. In addition, it was found that a C. albicans-specific 55-amino-acid region of the first intracellular loop, IC1, of the α-pheromone receptor, is required for the α-pheromone response of white cells, but not that of opaque cells. Finally, to test the generality of the white cell pheromone response, evidence was presented that the response occurs in all tested media and in all of the 27 tested strains, including a/a and α/α strains, derivatives of the common laboratory strain SC5314, and representatives from all of the five major clades. The white cell response to pheromone, therefore, proved to be a general characteristic of MTL-homozygous strains of C. albicans.
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Discovery of Anandamide, a Novel Lipid Signaling Molecule in Moss and Its ImplicationsKilaru, Aruna 01 January 2015 (has links)
No description available.
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Die Bedeutung von Osteoklasten für das Wachstum des Multiplen Myeloms / The impact of Osteoclasts on Multiple Myeloma growthJank, Christoph January 2011 (has links) (PDF)
Das Multiple Myelom ist eine Neoplasie die (fast) ausschließlich im Knochenmark lokalisiert ist. Verschiedene lösliche Faktoren und Zellinteraktionen sind für das Wachstum der Myelomzellen notwendig. Gute Untersuchungen zum Support der Myelomzellen gibt es für die Knochenmarkstromazellen. In dieser Arbeit wird gezeigt, dass auch Osteoklasten zum Zellwachstum der Myelomzellen beitragen. Es gibt Hinweise darauf dass dies z.T. durch Zell-zell-Interaktionen vermittelt wird. In der Analyse der Signalwege (MAPK-ERK-, STAT-3-, NF-Kappa-B- und AKT-Signalweg)zeigt sich ein unterschiedliches Aktivierungsmuster bei Support durch Osteoklasten oder Knochenmarkstromazellen. Weitere Signalwege sind wahrscheinlich an der Unterstützung des Wachstums der Myelomzellen beteiligt. Diese bedürfen einer weiteren Analyse. / The Multiple Myeloma is a neoplasia located in the bone marrow. Various soluble factors and cell-cell-Interactions contribute to multiple myeloma cell growth. There are good investigations for the support through bone marrow stroma cells. In this thesis is shown, that osteoclast contribute to the Myeloma cell growth as well. There are good suspicions that this is partly mediated through cell-cell-interactions. In the analysis of the signaling cascades (MAPK-ERK, STAT-3, NF-kappa-B and AKT)revealed a different activation pattern for support through osteoclasts or bone marrow stroma cells. Further signalling cascades might be involved in the support of Myeloma cell growth. Ongoing analysis on this subject is required.
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Glycoprotein hormone receptor signaling in the endosomal compartment / Glykoproteinhormon-Rezeptor Signaltransduktion im endosomalen KompartimentLyga, Sandra January 2017 (has links) (PDF)
G protein-coupled receptors (GPCRs) are the major group of cell-surface receptors that transmit extracellular signals via classical, G protein-dependent pathways into the cell. Although GPCRs were long assumed to signal exclusively from the cell-surface, recent investigations have demonstrated a possibly completely new paradigm. In this new view, GPCR continues signaling via 3´,5´-cyclic adenosine monophosphate (cAMP) after their agonist-induced internalization of ligand/receptor complexes into an intracellular compartment, causing persistent cAMP elevation and apparently specific signaling outcomes. The thyroid stimulating hormone (TSH) receptor is one of the first GPCRs, which has been reported to show persistent signaling after ligand removal (Calebiro et al., 2009). In the meantime, signaling by internalized GPCR become a highly investigated topic and has been shown for several GPCRs, including the parathyroid hormone receptor (Ferrandon et al., 2009), D1 dopamine receptor (Kotowski et al., 2011) and beta2-adrenergic receptor (Irannejad et al., 2013). A recent study on the beta2-adrenergic receptor revealed that internalized receptor not only participates in cAMP signaling, but is also involved in gene transcription (Tsvetanova and von Zastrow, 2014). However, a biological effect of GPCR signaling at intracellular sites, which would demonstrate its physiological relevance, still remained to be shown.
To investigate GPCR signaling from intracellular compartment under physiological condition, two different cellular models were utilized in the present study: intact ovarian follicles expressing luteinizing hormone (LH) receptors and primary thyroid cells expressing TSH receptors.
Intact ovarian follicles were obtained from a transgenic mouse expressing, a Förster/Fluorescence Resonance Energy Transfer (FRET) sensor for cAMP to monitor cAMP/LH receptor signaling. This study provides the first accurate spatiotemporal characterization of cAMP signaling, which is derived from different cell layers of an intact ovarian follicle. Additionally, it could be shown that cAMP diffusion via gap junctions is implicated in spreading the LH-induced cAMP signals from one the outermost (mural granulosa) to the innermost (cumulus oophorus) cell layer of an ovarian follicle. Interestingly, LH receptor stimulation was associated with persistent cAMP signaling after LH removal and negligible desensitization of the cAMP signal. Interfering with receptor internalization with a dynamin inhibitor dynasore did not only prevent persistent LH-induced cAMP signaling, but also impaired the resumption of meiosis in follicle-enclosed oocytes, a key biological effect of LH.
In order to investigate the downstream activation of protein kinase A (PKA) in primary thyroid cells, FRET sensors with different subcellular localization (plasma membrane, cytosol and nucleus) were transiently transfected into primary thyroid cells of wild-type mice via electroporation. Interestingly, TSH stimulation causes at least two distinct phases of PKA activation in the global primary thyroid cell, which are temporally separated by approximately 2 min. In addition, PKA activation in different subcellular compartments are characterized by dissimilar kinetics and amplitudes. Pharmacological inhibition of TSH receptor internalization largely prevented the second (i.e. late) phase of PKA activation as well as the subsequent TSH-dependent phosphorylation of CREB and TSH-dependent induction of early genes. These results suggest that PKA activation and nuclear signaling require internalization of the TSH receptor.
Taken together, the data of the present study provide strong evidence that GPCR signaling at intracellular sites is distinct from the one occurring at the cell-surface and is highly physiologically relevant. / G-Protein-gekoppelte Rezeptoren (GPCR) umfassen die größte Gruppe von Rezeptoren in der
Zellmembran und übermitteln extrazelluläre Signale via G-Protein-abhängige Signalwege in das Zellinnere. Obwohl lange Zeit die Wissenschaft davon ausging, das GPCR ausschließlich an der Zelloberfläche Signale weiterleiten, zeigen Studien der letzten Jahre eine vollkommen neuartige Signalweiterleitung aus dem Zellinneren. In dieser neuen Sichtweise, vermitteln GPCR nach Agonist-induzierter Internalisierung des Liganden/Rezeptor-Komplexes in das Zellinnere weiterhin zyklische Adenosin-3´,5´-monophosphat (cAMP)-Signale, was zu einer dauerhaften cAMP-Erhöhung und einem spezifischen Ergebnis der Signaltransduktion führt. Einer der ersten GPCR, für den gezeigt wurde, dass Signale aus dem Zelleninneren übertragen werden können, war der Thyreoidea-stimulierendes Hormon (TSH) Rezeptor. In der Zwischenzeit wurde die Signalübertagung von bereits internalisierten Rezeptoren für weitere GPCR gezeigt, inklusive des beta2-adrenergen Rezeptors. Vor kurzem demonstrierte eine Studie des beta2-adrenerge Rezeptors, dass die intrazellulare GPCR-Signalübertragung nicht nur an der cAMP-Weiterleitung sondern auch an der Gentranskription beteiligt ist. Bis jetzt konnte jedoch noch kein Zusammenhang zwischen der GPCR-Signaltransduktion aus dem Zellinneren und einem biologischen Effekt mit physiologischer Relevanz hergestellt werden.
Um GPCR-Signaltransduktion im Zellinneren unter physiologischen Bedingungen zu untersuchen, wurden in der aktuellen Arbeit zwei unterschiedliche zelluläre Modelle verwendet: Intakte Follikel eines Ovars, welche luteinisierende Hormon (LH) Rezeptoren exprimieren und TSH-Rezeptoren-exprimierende primäre Schilddrüsenzellen.
Die Follikel wurden aus einer transgenen Maus, die einen Förster/Fluoreszenz Resonanz Energie Transfer (FRET) Sensor für cAMP exprimiert, gewonnen, um cAMP/LH-Signaltransduktion zu messen. Diese Arbeit zeigt die erste exakte, zeitliche und räumliche Charakterisierung der LH- induzierten cAMP-Signaltransduktion in intakten Follikeln des Ovars. Des Weiteren konnte gezeigt werden, dass die Diffusion von cAMP via Gap Junctions ein wichtiger Bestandteil bei der Übermittlung des LH-induzierten cAMP-Signals von der äußeren (Mural granulosa) zur inneren (Cumulus oophorus) Zellebene eines Follikels darstellt. Interessanterweise ergab die LH- Rezeptor Stimulation nach Entfernung des Liganden LH ein anhaltendes cAMP-Signal sowie eine unwesentliche Desensitization des cAMP-Signals. Die Inhibition der Rezeptorendozytose mit Dynasore verhinderte nicht nur das LH-induzierte anhaltende cAMP-Signal sondern beeinflusste auch die Wiederaufnahme der Meiose durch die Follikel-eingeschlossene Oozyte, einer der
wichtigsten biologischen Aufgaben von LH.
Um den Einfluss der TSH-Rezeptorinternalisierung auf die PKA-Aktivität zu untersuchen, wurden
primäre Schilddrüsenzellen von FVB-Mäusen, mit FRET-basierenden Protein Kinase A (PKA) Sensor exprimiert werden, via Elektroporation transfiziert. Die Ergebnisse zeigen, dass eine TSH- vermittelte Stimulation des Rezeptors mindestens zwei kinetisch und räumlich unterschiedliche PKA-Signale in Schilddrüsenzellen auslöst, die zeitlich voneinander getrennt sind. Durch die Inhibierung des TSH-Rezeptorinternalisierung konnte gezeigt werden, dass das zweite PKA-Signal sowie die darauffolgende TSH-abhängige Phosphorylierung des Trankriptionsfaktors CREB und die TSH-abhängige Regulierung von Gen Expression vermindert ist. Diese Befunde geben Aufschluss über die Notwendigkeit der Internalisierung des Rezeptors in das Zellinnere für eine effektive PKA- und Zellkern-Signaltransduktion.
Zusammenfassend lässt sich sagen, dass die Ergebnisse dieser Arbeit neue, und wichtige Erkenntnisse über den Mechanismus der GPCR-Signalweiterleitung im Zellinneren und erstmals
einen Einblick über die biologische Relevanz der Rezeptorinternalisierung liefern.
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Characterization and optimization of low-swing on-chip interconnect circuitsIrfansyah, Astria Nur, Electrical Engineering & Telecommunications, Faculty of Engineering, UNSW January 2008 (has links)
Low-swing on-chip interconnect circuits have been viewed as alternative solutions to the problem of delay and power increase of on-chip interconnects. This thesis aims to characterize and optimize several basic low-swing interconnect circuits, by developing simple delay and power estimation methodologies. Accuracies of the proposed methods are validated against SPICE-based simulations on the 90nm technology node. Based on the delay and power estimation methods developed, optimum power-delay trade-off curves are obtained and directly used for comparison among different interconnect circuit strategies. Three low-swing techniques are included, i.e. conventional level converter (CLC), pseudodifferential interconnect circuit (PDIFF), and current-mode signaling (CM). These techniques represent significantly different driver and receiver topologies, where CLC uses lower supply voltage of a normal inverter driver, PDIFF uses NMOS only drivers, while CM has a low impedance termination at the receiving end. In addition, an optimized full-swing repeater-based technique is included as a baseline for comparison. A simplified repeater performance estimation technique considering ramp input signals is also proposed. The most important step in estimating delay of different driver circuits is the accurate estimation of transistor effective resistance, which considers velocity saturation effects and voltage transition patterns. Optimization for the CM circuit for on-chip interconnects requires completely different treatment than the voltage-mode circuits, due to the different and more complex effective driver resistance and termination resistance modeling. Sizing the driver and receiver transistors should be done simultaneously as their resistive values which affect its performance are dependent on each other. Optimum transistor sizing is very dependenton the required voltage swing chosen. Results of our comparisons show that optimized CLC (reduced voltage supply) repeaters appears to give the best general performance with a slight delay overhead compared to full-swing repeaters. The fact that CLC with repeaters has shorter delay than single-segment CM and PDIFF highlights the effectiveness of repeater structures in long wires. The inclusion of inductance and closed-form solutions to derive optimum transistor sizings for various low-swing interconnect circuits may be developed as a future work using delay and power estimation models presented in this thesis, which is a challenging task to do considering the non-linear equations involved.
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Signaling pathways in the activation and proliferation of Drosophila melanogaster blood cellsZettervall, Carl-Johan January 2005 (has links)
<p>The larva of the fruit fly Drosophila melanogaster is an excellent model to study the molecular control of innate cellular immune responses. Cellular responses take place, and can be studied, following infestation of the wasp Leptopilina boulardi. This response includes proliferation and activation (differentiation) of the blood cells (hemocytes). In a successful anti-parasitic response, an immune-induced lineage of hemocytes, the lamellocytes, forms a cellular capsule covering and killing the foreign intruder. I will in this thesis present data about the finding and characterization of a novel marker that is expressed specifically in the hemocytes, the Hemese gene. I furthermore describe the construction of a useful tool, the transgenic Hemese-Gal4 fly, which enables blood cell specific expression of any gene of interest. By using the Hemese-Gal4 fly in a directed screen, I have found that a surprisingly large number of genes, that in turn are members of seemingly diverse signaling pathways, are able to induce a cellular response. In many cases their expression is also associated with a blood cell tumor phenotype. Overexpression of certain genes, such as hopscotch (a Drosophila Jak homologue) and hemipterous (a c-jun kinase kinase) lead to the formation of lamellocytes. Other genes may control the cell number, such as Egfr and Ras, as their expression produced a massive in increase the numbers of hemocytes. A third group of genes, including, e.g. Alk, Rac1 and Pvr give a mixed response, promoting both hemocyte proliferation and activation. Surprisingly, the suppression of WNT signaling in hemocytes lead to hemocyte activation. In one case, with a UAS-Pvr dominant negative construct, we observe a reduction of the circulating blood cells in uninfested larva. The expression of DN-Pvr additionally contributes to reduce encapsulation rates in larvae subjected to Leptopilina infestation. In conclusion: the control of blood cells in larval hematopoiesis, and during parasitic wasp attacks, is complex and may involve multiple pathways. In a broader sense, the gene functions found in the directed screen may have implications also for understanding the molecular control of mammalian myeloid lineage blood cells.</p>
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Orexin Receptors in Recombinant CHO Cells : Signaling to Short- and Long-Term Cell ResponsesAmmoun, Sylwia January 2005 (has links)
<p>Recently discovered neuropeptides orexins (orexin-A and -B) act as endogenous ligands for G-protein-coupled receptors called OX<sub>1</sub> and OX<sub>2</sub> receptors. Our previous studies have established model systems for investigation of the pharmacology and signaling of these receptors in recombinant CHO cells. OX<sub>1</sub> receptor-expressing CHO cells were mainly utilized in this thesis.</p><p>Orexin-A and -B activate both OX<sub>1</sub> and OX<sub>2</sub> receptors. However, orexin-B is less potent in activating OX<sub>1</sub> receptors than orexin-A, whereas the peptides are equipotent on OX<sub>2</sub> receptors. We have performed mutagenesis on orexin-A to investigate the basis for this selectivity. We show that OX<sub>2</sub> receptor is generally less affected by the mutations and thus OX<sub>2</sub><sup> </sup>receptor appears to have less strict requirements for ligand binding, likely explaining the lack of difference in affinity/potency between orexin-A and orexin-B on OX<sub>2</sub> receptor.</p><p>The other studies focus on orexin receptor signaling. OX<sub>1</sub> receptors are shown to regulate adenylyl cyclase both in positive and negative manner, activate different MAP-kinases (ERK1/2 and p38) and induce cell death after long-lasting stimulation. Adenylyl cyclase regulation occurs likely through three different G-protein families, Gi, Gs and Gq. For ERK1/2, several downstream pathways, such as Ras, Src, PI3-kinase and protein kinase C (PKC) are implicated. OX<sub>1</sub> receptor-mediated activation of ERK is suggested to be cytoprotective whereas p38 MAP-kinase induces programmed cell death. </p><p>Three particularly interesting findings were made. Firstly, novel PKC δ (delta) is suggested to regulate adenylyl cyclase, whereas conventional and atypical PKCs are involved in activation of ERK. Secondly, adenylyl cyclase and ERK activation is fully dependent on extracellular Ca<sup>2+</sup>. Further experiments suggest that the previously discovered receptor-operated Ca<sup>2+</sup> influx is not affecting the downstream effectors of orexin receptors but that it instead enables orexin receptors to couple to several signal cascades. Thirdly, upon inhibition of caspases, classical mediators of programmed cell death, OX<sub>1 </sub>receptor-mediated cell death is not reversed, but instead the pathways to death are altered so de novo gene transcription is no longer required for cell death.</p>
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The Role of Habitat in Crocodilian CommunicationDinets, Vladimir 12 April 2011 (has links)
Crocodilians (crocodiles, alligators, caimans and gharials) have a particular category of signals used for long-distance communication of location and status. These signals are composed of acoustic and non-acoustic components with different physical properties, such as vocal sounds, slaps, infrasound, odor and postures. A survey of extant species and a comparative study of allopatric conspecific populations inhabiting different habitats show that the composition of these signals is adjusted to optimize their ability to carry information in each habitat. Studies of animals living in changing habitats and of animals inhabiting different habitats within the same geographical areas show that these adaptations are evolved differences between populations and species rather than a result of behavioral adjustments by individual animals in response to habitat structure. Details of adjustment process help elucidate information about the functions of each signal component. Experimental data obtained in the course of the study show that crocodilians have the ability to locate the sound underwater. In addition, novel information on signaling by almost all extant crocodilian species is provided. This information gives important new evidence for solving the long-standing controversy of crocodilian systematic, showing that false gharials are aberrant crocodiles rather than members of the gharial lineage. It also sheds some light on the evolution of crocodilian signaling, allowing to plot the events of signal evolution on the phylogenetic tree, and explaining the puzzling absence of small species among extant crocodilians.
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Orexin Receptors in Recombinant CHO Cells : Signaling to Short- and Long-Term Cell ResponsesAmmoun, Sylwia January 2005 (has links)
Recently discovered neuropeptides orexins (orexin-A and -B) act as endogenous ligands for G-protein-coupled receptors called OX1 and OX2 receptors. Our previous studies have established model systems for investigation of the pharmacology and signaling of these receptors in recombinant CHO cells. OX1 receptor-expressing CHO cells were mainly utilized in this thesis. Orexin-A and -B activate both OX1 and OX2 receptors. However, orexin-B is less potent in activating OX1 receptors than orexin-A, whereas the peptides are equipotent on OX2 receptors. We have performed mutagenesis on orexin-A to investigate the basis for this selectivity. We show that OX2 receptor is generally less affected by the mutations and thus OX2 receptor appears to have less strict requirements for ligand binding, likely explaining the lack of difference in affinity/potency between orexin-A and orexin-B on OX2 receptor. The other studies focus on orexin receptor signaling. OX1 receptors are shown to regulate adenylyl cyclase both in positive and negative manner, activate different MAP-kinases (ERK1/2 and p38) and induce cell death after long-lasting stimulation. Adenylyl cyclase regulation occurs likely through three different G-protein families, Gi, Gs and Gq. For ERK1/2, several downstream pathways, such as Ras, Src, PI3-kinase and protein kinase C (PKC) are implicated. OX1 receptor-mediated activation of ERK is suggested to be cytoprotective whereas p38 MAP-kinase induces programmed cell death. Three particularly interesting findings were made. Firstly, novel PKC δ (delta) is suggested to regulate adenylyl cyclase, whereas conventional and atypical PKCs are involved in activation of ERK. Secondly, adenylyl cyclase and ERK activation is fully dependent on extracellular Ca2+. Further experiments suggest that the previously discovered receptor-operated Ca2+ influx is not affecting the downstream effectors of orexin receptors but that it instead enables orexin receptors to couple to several signal cascades. Thirdly, upon inhibition of caspases, classical mediators of programmed cell death, OX1 receptor-mediated cell death is not reversed, but instead the pathways to death are altered so de novo gene transcription is no longer required for cell death.
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Structural Determinants of 5-Ht1a Receptor Interaction With Gαi SubunitsZhou, Yi Yuan 08 February 2011 (has links)
The 5-hydroxytryptamine (5-HT) system modulates numerous physiological and behavioural processes, and dysfunction within this system underlies many behavioural disorders, such as major depression. The 5-HT1A receptor is the primary somatodendritic autoreceptor that controls the firing rate of 5-HT neurons, but is also coupled to numerous signalling pathways. An understanding of 5-HT1A receptor signalling may lead to the development of antidepressant drugs that selectively target therapeutic pathways in treating depression. The 5-HT1A receptor is coupled to inhibitory G-proteins via its intracellular loops 2 and 3. Point mutations within these loops selectively uncouple receptor signalling pathways. In this thesis, I addressed whether mutant receptors’ uncoupling from signalling pathways is associated with alteration in G-protein interaction and coupling. Using bioluminescence resonance energy transfer (BRET) to monitor receptor-G-protein interactions, we show that both wild-type and mutant receptors demonstrate a saturable interaction with Gαi protein in unstimulated conditions. Addition of 5-HT increased the BRET signal for the wild-type 5-HT1A receptor, and this increase was blocked by a 5-HT1A receptor antagonist and G-protein blocker (pertussis toxin). Mutant receptors that were deficient in Gαi signalling, but not those that still signalled to Gαi, failed to respond to receptor activation with increased receptor-Gαi interaction. Pull down studies verified the basal and agonist-induced interaction of 5-HT1A receptors with Gαi proteins. In conclusion, we have shown that the 5-HT1A receptor interacts with Gαi consistent with a pre-coupled model and that 5-HT-induced activation enhances this interaction and requires specific residues in the intracellular loops.
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