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Showing 61 to 70 of 76 (0.029 seconds)Spelling suggestions: "subject:"proteinkinase A"" "subject:"proteinkinasen A""
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Nachweis Proteinkinase C abhängig exprimierter Gene in AstrozytomenSchulz, Timm 19 September 2003 (has links)
Die Proteinkinase C (PKC) ist eine wichtige Signaltransduktionskomponente, deren Aktivierung die Expression zahlreicher Gene induziert und zur Zelldifferenzierung und Zellproliferation führt. Ein besonders hohes Expressionsniveau der PKC findet man in vielen Tumoren. So korreliert in malignen Gliazellen das Expressionsniveau der PKC mit deren Wachstumsgeschwindigkeit. Es wird angenommen, daß die aktivierte PKC eine wichtige Rolle in der Tumorpromotion hat. In der vorliegenden Arbeit wurde untersucht, ob in Astrozytomzellinien Gene zu finden sind, die nach PKC-Aktivierung durch den Phorbol-Ester TPA differentiell exprimiert werden. Zunächst wurden kultivierte Zellen der Astrozytomzellinie LN-405 mit TPA respektive dem PKC-Inhibitor Chelerythrin behandelt. Nach Gewinnung der mRNA aus der zuvor isolierten RNA wurden in einem mehrstufigem PCR-Verfahren (SSH) cDNA-Abschnitte gewonnen, die zu vermeintlich differentiell exprimierten Genen gehören. Diese cDNA-Abschnitte wurden in Plasmid-Vektoren eingefügt, kloniert und zur Bestimmung sequenziert. Um falsch positive Sequenzen zu erkennen, wurden die zuvor radioaktiv markierten cDNA-Abschnitte mit Northernblots hybridisiert. Gleichzeitig ließ sich so ein zeitabhängiger Anstieg der Expression nach PKC-Stimulation untersuchen. Durch den PCR-Select-Assay (SSH) konnten insgesamt 11 Gene gefunden werden, die sich in der radioaktiven Northernblot-Hybridisierung, als nach PKC-Aktivierung differentiell exprimiert, darstellen ließen. Dabei bestätigt der gefundene Zusammenhang zwischen PKC-Aktivierung und differentieller Exprimierung bei fünf der 11 Gene (IL-8, Calpain, Interferon-gamma Rezeptor 2, Methionin Adenosyltransferase, beta-2 adrenerger Rezeptor) Ergebnisse anderer Autoren, wobei dieser Zusammenhang nur bei zwei Genen (IL-8 und Calpain) auch in Astrozytom- bzw. Gliom-Zellen schon früher gezeigt werden konnte. Sechs Gene (M-Phase Phosphoprotein-1, ect2-Onkogen, ERM-Gen, Ornithin-Decarboxylase-Antizym 2, MHC-bindendes Protein 2, Sequenz aus Cosmid F0811) wurden in der vorliegenden Arbeit erstmalig als PKC-abhängig exprimiert beschrieben. Die gefundenen Gene haben auf verschiedene Funktionen der Zellen Einfluß. So beeinflussen sie die Regulation des Zellzyklus (MPP1, ect2-Oncogen), die Immunregulation (MBP-2, IL-8, Interferon-gamma Rezeptor 2), die Signaltransduktion (beta-2 AR), die Transkription (ERM-Gen), die Proteinsynthese (ODC-Antizym, MAT), die Wachstumskontrolle (ODC-Antizym) und die Regulation der PKC selbst (Calpain). Für fünf Gene läßt sich ein eindeutiger Zusammenhang mit der Tumorpromotion herstellen: IL-8 (Angioneogenese), MBP-2 (Immunsuppression), ERM-Gen (Transkriptionspromotion), MAT (allgemein fördernder Einfluß auf den Metabolismus) und ect2-Oncogen (Oncogen). / The protein kinase C (PKC) is one of the major signal transduction systems and its activation leads to the induction of the expression of several genes, to cell differentiation and cell proliferation. Very high expressed PKC are found in many tumors. In malignant glia cells the expression of PKC correlates with their proliferation rate. The PKC activity has an important role for the tumor promotion. The object of this paper, was to investigated, if there are genes differentialy expressed after activation of PKC through the phorbol-ester TPA in astrocytoma cell lines. The astrocytoma cell line LN-405 was incubated with TPA and the PKC-inhibitor chelerythrine respectively. After isolation of RNA and mRNA the suppression subtractive hybridization (SSH) was used to isolate differentially expressed cDNA fragments. These cDNA fragments were inserted into the T/A cloning vector, cloned and sequenced. To detect false positives the cDNA fragments were analysed with northern blot technique. Examined was also a time-dependent acceleration of expression after TPA treatment. 11 genes were detected by suppression subtractive hybridization, showing differentially expressed in the northern blot hybridization. Five of the genes were found differentially expressed after PKC activation before (IL-8, calpain, interferon gamma receptor 2, beta-2-adrenergic receptor, methionine adenosyltransferase alpha), two of these genes (IL-8, calpain) also in astrocytoma- and glioma-cells respectively. Six genes (M-phase phosphoprotein 1, ect2-onkogene, erm gene, ornithine decarboxylase antizyme 2, MHC binding protein 2, sequence from Cosmid F0811) were described as PKC dependent expressed for the first time. The genes detected influence several cell functions. They are involved in cell-cycle regulation (MPP1, ect2-oncogene), immuneregulation (MBP-2, IL-8, interferon gamma receptor 2), signal transduction (beta 2 adrenergic receptor), transcription (erm-gene), synthesis of proteins (ODC-antizyme 2, MAT), growth control (ODC-antizyme) and regulation of PKC (Calpain). Five genes show a clear connection to tumor promotion: IL-8 (angioneogenesis), MPB-2 (immunesuppression), erm gene (promotion of transcription), MAT (promotion of metabolism) and ect2-oncogene (oncogene).
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Regulierung und Verfügbarkeit von Apolipoprotein E in AstrozytenHamker, Ulrike 24 May 2005 (has links)
Apolipoprotein E (ApoE) ist eine verbreitet vorkommende Komponente der Plasmalipoproteine und spielt eine Schlüsselrolle bei Lipidtransport und Cholesterin-Homöostase über den Low Density Lipoprotein Rezeptor. Im ZNS wird ApoE hauptsächlich von Astrozyten synthetisiert und sekretiert. ApoE-Isoformen haben unterschiedliche Wirkung auf eine Zahl von pathologischen Prozessen, die der Alzheimerschen Krankheit zugrunde liegen. Um die Rolle des ApoE für die Alzheimersche Krankheit zu erhellen, ist es wichtig Kenntnisse über seine Regulation zu erlangen. Ein Ziel dieser Arbeit war zu untersuchen, ob die „Second-Messenger“-Signalpfade „Adenylatcyclase/Proteinkinase A (PKA)“ und/oder „Phospholipase C/Proteinkinase C (PLC/PKC)“ in die Regulation der astrozytären ApoE Sekretion eingreifen. Hierfür wurden primäre hippocampale Astrozytenkulturen von Ratten mit verschiedenen Analoga, Rezeptoragonisten und Neurotransmittern, die diese Signalpfade beeinflussen, inkubiert. Dibutyryl-cAMP (cAMP-Analogon) erhöhte die ApoE Sekretion. Auch Rezeptoragonisten des Adenylatcyclase/PKA-Signalwegs beeinflussten die ApoE Sekretion. Isoproterenol (beta-Adrenorezeptoragonist) erhöhte die ApoE Sekretion, während Clonidine (alpha-2 Adrenorezeptoragonist) sie senkte. Der PKC-Aktivator Phorbol 12-Myristat 13-Acetat senkte die ApoE Sekretion und kehrte die dibutyryl-cAMP-vermittelte Erhöhung der ApoE Sekretion um. Arterenol (alpha-1 Adrenorezeptoragonist) und Serotonin (Neurotransmitter) erhöhten die ApoE Sekretion, wohingegen Carbachol (Acetylcholiner muskarinischer Rezeptoragonist) die ApoE Sekretion senkte. Es wird gezeigt, dass die verwendeten Substanzen einen von der ApoE Sekretion verschiedenen Einfluss auf die Sekretion des Nervenwachstumsfaktors (NGF) haben. Dies legt die Vermutung nahe, dass die beobachteten Ergebnisse nicht auf einen generellen Effekt der Proteinsynthese zurückzuführen sind. Es kann gefolgert werden, dass die astrozytäre ApoE Sekretion von Faktoren beeinflusst werden kann, die die intrazelluläre Konzentration von cAMP verändern oder die PKC aktivieren. Das zweite Ziel der Arbeit war zu untersuchen ob Amyloid Fragmente einen Einfluss auf die astrozytäre ApoE Sekretion haben. Senile Amyloid-Plaques in Alzheimer-Gehirnen zeigen eine ApoE-Immunreaktivität, Astrozyten die diese Plaques umgeben dagegen nicht. Es wird gezeigt, dass gealtertes fibrilläres Amyloid (1-40) die ApoE Sekretion erhöht. Das sekretierte ApoE wird durch die, die Zellen umgebenden Amyloid-Konglomerate, gebunden. Die verwendeten Amyloid Fragmente beeinflussten nicht die Menge des sekretierten basischen Fibroblastenwachstumsfaktors. Dies legt nahe, dass die beobachteten Ergebnisse nicht auf einen generellen Effekt der Proteinsynthese zurückzuführen sind. / Apolipoprotein E (apoE) is an abundant component of plasma lipoproteins that plays a key role in lipid transport and cholesterol homeostasis via the low density lipoprotein receptor. In the CNS, apoE is synthesised and secreted especially by astrocytes. ApoE isoforms have different effects on a number of pathological processes underlying Alzheimer’s disease. Therefore, understanding the regulated synthesis of apoE is important for determining its role in Alzheimer’s disease. One aim of this work was to examine whether the second-messenger-pathways „adenylyl cyclase/proteinkinase A (PKA)“ and/or „phospholipase C/proteinkinase C (PLC/PKC) are involved in the regulation of apoE secretion in astrocytes. Therefore rat primary hippocampal astrocyte cultures were incubated with various analogues, receptor agonists and neurotransmitters which influence these pathways. Dibutyryl-cAMP (cAMP analogue) increased the apoE secretion. ApoE secretion was also modulated by receptor agonists of the adenylyl cyclase/PKA pathway. Isoproterenol (beta-adrenoceptor agonist) enhanced, while Clonidine (alpha 2-adrenoceptor agonist) decreased, the secreted apoE. In contrast, the PKC activator phorbol 12-myrisate 13-acetate decreased the apoE secretion. It also reversed the effects of dibutyryl-cAMP. Arterenol (alpha 1-adrenoceptor) and serotonin (neurotransmitter) enhanced, whereas carbachol (acetylcholine muscarinic receptor agonist) deceased secreted apoE. It is shown, that the used substances have different effects on the secretion of the nerve growth factor (NGF) as compared to apoE secretion, suggesting that the results obtained were unlikely to be due to a general effect on protein synthesis. It can be concluded that actrocytic apoE production can be regulated by factors that affect cAMP intracellular concentration or activate PKC. The second aim of this work was to examine whether amyloid fragments have an effect on the apoE secretion of astrocytes. Senile amyloid plaques in Alzheimer’s disease brains show apoE immunoreactivity, astrocytes which surround them do not. It is shown, that aged, fibrillic amyloid (1-40) increases apoE secretion. The secreted apoE is bound to the surrounding amyloid conglomerates. The used amyloid fragments did not increase or decrease basic fibroblast growth factor secretion, suggesting that the results obtained were unlikely to be due to a general effect on protein synthesis.
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Energy Metabolism and the Control of Stem Cell Proliferation in PlanariansFrank, Olga 27 October 2020 (has links)
Cell turnover is a common feature of many organs in all animals and is required to maintain organ structure and function. It is achieved by a tightly regulated balance between cell death and cell division, which can be re-adjusted in response to injury and nutrient availability. How the balance between dying and dividing cells is coordinated has however remained unclear. Planarians represent an important model for studying cell turnover in adult animals, because all tissues undergo continuous cell turnover and a single stem cell type – the neoblast – is the exclusive source of all new cells. Moreover, planarians change their body size proportionally and reversibly depending on the nutritional status: feeding induces rapid and transient neoblast proliferation that results in animal growth, while starvation increases the rate of cell death, leading to de-growth. Importantly, also during starvation neoblasts keep proliferating at a basal-level. The hypothesis I addressed with my thesis research is that planarian energy metabolism might be a central mediator of cell turnover, particularly proliferation control and growth. I approached this hypothesis at several levels, including the characterization of the planarian energy metabolism and energy stores, the dependency of proliferation on the diet, and genetic requirements of proliferation control during starvation and feeding.
I found that planarians have orthologs of key enzymes of most animal metabolic pathways, but, surprisingly, seem to lack fatty acid synthase. This suggests that planarians are likely not only auxotrophic for cholesterol, but also for fatty acids. I described that planarians store energy as triacylglycerols (TAGs, stored in lipid droplets) and glycogen, with the intestine as the main storage organ. Interestingly, the amount of TAGs and glycogen changes with size and is higher for larger animals, suggesting a regulatory interplay with the known size-dependency of growth/degrowth rates. Further, we demonstrated that the energy stores are the physiological basis of Kleiber’s law that describes the near-universal scaling between metabolic rate and body mass. I further showed that proliferation occurs in three different modes, one during starvation when proliferation is maintained at basal levels and two after feeding, an initial proliferation mode (at three hours after feeding), which is diet independent and a later proliferation (at 24 hours after feeding), which is diet dependent. The two feeding-induced proliferation modes differ not only in their diet-dependencies, but also in their gene expression profiles, as assessed by RNA-sequencing. To identify genes involved in proliferation regulation, I assessed the requirements of different candidate genes in all three proliferation modes in a small-scale RNA interference screen. This screen revealed that insulin signaling, TORC1 and FGFR are involved in regulating basal proliferation during starvation and – most interestingly –that AMP-activated protein kinase (AMPK)-depleted animals showed increased proliferation during starvation at levels characteristic of recently fed animals. This result uncovered AMPK as a modulator that adjusts the neoblast proliferative activity to the nutritional state, potentially independently of TOR.
In sum, my work shows how energy metabolism and storage are coordinated with proliferation and growth in planarians and identified AMPK as a central modulator that adjust proliferation to cellular energy states. I discuss potential mechanisms by which AMPK modulates proliferation and putative links between AMPK and cell death, the second process of cell turnover. The energy state as the central mediator of cell turnover and the key players and mechanisms that my work revealed in planarians might also apply across different species:Chapter 1
1. Introduction 1
1.1 Cell turnover is a crucial process for tissue homeostasis 1
1.2 Cell division 2
1.2.1 Control mechanisms of cell division 2
1.2.1.1 Cell cycle machinery 2
1.2.1.2 Organization of the cell cycle control system – cell-cycle intrinsic regulation by Cdk-cyclin complexes 3
1.2.1.3 External control of cell cycle progression 4
1.2.1.4 Metabolic control of cell cycle progression 6
1.2.2 Metabolic requirements of proliferating cells 10
1.2.2.1 The energy stores 11
1.3 Cell death 13
1.4 Suggested mechanisms that coordinate cell death and division and their caveats 14
1.5 Planarians as a model to study cell turnover 16
1.6 Planarian body anatomy 18
1.7 Planarian stem cell system 19
1.7.1 Neoblasts form a heterogeneous population 19
1.7.2 Neoblast proliferative activity 21
1.7.3 Neoblast cell cycle machinery 22
1.7.4 Regulation of neoblast proliferative activity 22
1.8 Cell death in planarians 23
1.9 Mechanisms that coordinate the rate of dividing and dying cells in planarians still remain elusive 24
1.10 Scope of the thesis 24
Chapter 2
2. Planarian energy metabolism and the regulation of planarian growth dynamics 26
2.1 Introduction 26
2.2 Part 1: Planarian energy metabolism 27
2.2.1 The metabolic machinery of S. mediterranea 27
2.2.2 Planarian energy stores 30
2.2.2.1 Visualization of lipid and glycogen storage compartments in planarians 30
2.2.2.2 Investigation of feeding-dependent changes in lipid and glycogen stores 31
2.3 Part 2: Role of planarian organismal energy stores in regulating their growth and degrowth dynamics 36
2.3.1 Background information about known aspects of growth and degrowth dynamics in planarians 36
2.3.1.1 Growth and degrowth arise mainly from changes in cell number 36
2.3.1.2 Growth and degrowth rates are size dependent 37
2.3.2 Energy stores increase disproportionately with size and strongly contribute to the size-dependent dry mass increase 38
2.3.3 Metabolic rate and energy intake are unlikely causes of the size-dependency of the energy stores 41
2.4 Summary and Discussion 43
2.4.1 Part 1: First insights into planarian energy metabolism 43
2.4.1.1 Core planarian metabolic pathways 43
2.4.1.2 Characterization of planarian energy stores 44
2.4.2 Part 2: Implications of size-dependent behavior of planarian energy stores 44
2.4.2.1 Role of energy stores as the physiological origin of Kleiber’s law in planarians 44
2.5 Outlook 46
Chapter 3
3. Towards understanding a systems-level regulation of neoblast proliferative activity 48
3.1 Introduction 48
3.2 Assay development for quantitative determination of proliferating cells 50
3.3 Food quantity and quality affect the later proliferation phase, but not the initial response to feeding 53
3.4 Deep sequencing time course provides insights into gene-expression changes in response to feeding 56
3.5 Discussion 59
3.5.1 Evidence for feeding-induced neoblast regulation at the G0/G1-to-S transition 59
3.5.2 Three distinct modes of neoblast proliferation 59
3.5.3 Early and late proliferation modes show distinct transcriptional profiles 59
3.5.4 Implications from feeding and gene expression profiling experiments 60
3.5.4.1 Potential explanations for diet dependence of the late proliferation mode 60
3.5.4.2 Potential mechanisms of diet-independent early proliferation response 61
3.5.5 Summary and Outlook 61
Chapter 4
4. Towards identifying the mechanisms underlying the regulation of neoblast proliferation 63
4.1 Introduction 63
4.1.1 Chosen gene candidates and their known role in proliferation 64
4.2 RNAi-mediated depletion of candidate genes to test their regulatory role in proliferation 67
4.2.1 Assay design and optimization for the functional RNAi screen 67
4.2.2 Results of small-scale RNAi screen 69
4.3 AMPK - a potential integrator of neoblast proliferation to the nutritional state of the animal 73
4.3.1 AMPK and LKB1 knockdown increases proliferation during starvation 73
4.3.2 AMPK depletion-phenotype of increased proliferation during starvation seems to be TOR independent 73
4.4 Discussion 76
4.4.1 Evidence for a mechanism that regulates basal proliferation during starvation 76
4.4.2 AMPK integrates neoblast activity in response to feeding 77
4.4.2.1 Implications of my observations 77
4.4.2.2 Possible experiments to test the role of AMPK during the regulation of proliferation 78
4.4.3 AMPK potentially regulates proliferation independently of TOR 79
4.4.4 An evolutionarily conserved stem cell switch? 80
4.4.5 Summary and Outlook 80
Chapter 5
5. Discussion and Outlook 81
5.1 Cell-autonomous roles of AMPK in proliferation regulation 83
5.1.1 Independent regulation of ribosomal translation elongation as a potential modulator of neoblast proliferation 83
5.1.2 AMPK might regulate cell cycle progression directly 85
5.1.3 AMPK might regulate symmetric versus asymmetric cell division 85
5.2 Cell non-autonomous roles of AMPK in proliferation regulation 86
5.2.1 AMPK might modulate the release of lipid stores 86
5.3 Possible role of AMPK in regulation of autophagic cell death 87
5.4 AMPK as a potential modulator of cell turnover that couples cell proliferation and cell death to the animal’s energy state 88
5.5 Summary and Outlook 89
Materials and Methods 91
List of Figures 106
List of Tables 107
Acknowledgments 108
References 110
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Die Proteinkinase A-vermittelte Ekto-Phosphorylierung des Membranproteins FAT/CD36 hemmt die Aufnahme freier Palmitinsäure durch humane ThrombozytenMähl, Philipp Henning 13 October 2003 (has links)
Untersucht wurde der Zusammenhang zwischen der Proteinkinase A-vermittelten Ekto-Phosphorylierung des Membranproteins FAT/CD36 [Hatmi et al. 1996] und der initialen zellulären Aufnahme langkettiger Fettsäuren. Wir zeigten einen inhibitorischen Effekt auf die initiale Palmitinsäure-Aufnahme humaner Thrombozyten unter den Bedingungen der Ekto-Phosphorylierung von FAT/CD36. Damit kann erstmalig ein Mechanismus für die kurzfristige Regulation der proteinvermittelten Aufnahme langkettiger Fettsäuren vorgeschlagen werden. Für die Bearbeitung der Fragestellung wurden die Isolation "ruhender", morphologisch und funktionell intakter humaner Thrombozyten und eine Methode zur Messung der initialen Palmitinsäure-Aufnahme etabliert. Die Kinetik der Palmitinsäure-Aufnahme humaner Thrombozyten wurde charakterisiert und bestätigt, dass ein wesentlicher Anteil der initialen Aufnahme proteinvermittelt erfolgt. Die von Hatmi und Co-Autoren beschriebene Ekto-Proteinkinase A-vermittelte, cAMP-abhängige Phosphorylierung von FAT/CD36 [Hatmi et al. 1996] konnte unter unseren experimentellen Bedingungen nachvollzogen werden. Die Ekto-Phosphorylierung von FAT/CD36 ging mit einer signifikanten Abnahme der initialen Palmitinsäure-Aufnahme einher. Die maximale Abnahme auf 72 % des Kontrollwerts wurde bei einer extrazellulären ATP-Konzentration von 0,5 nM erreicht. Der inhibitorische Effekt liess sich durch Co-Inkubation mit dem spezifischen Proteinkinase A-Inhibitorpeptid PKI 5-24 oder mit beta-gamma-ATP aufheben. Der Effekt war durch Dephosphorylierung mit Alkalischer Phosphatase vollständig reversibel. Bei extrazellulären ATP-Konzentrationen zwischen 10 pM und 15 nM war der inhibitorische Effekt der Ekto-Phosphorylierung auf die Palmitinsäure-Aufnahme signifikant. ATP-Konzentrationen über 15 nM verminderten den Effekt, bei über 5 µM ATP war kein Effekt nachzuweisen. Wir konnten ausschliessen, dass die Aufhebung durch ATP-Abbauprodukte verursacht wurde. Unsere Beobachtungen deuten auf einen regulatorischen Einfluss höherer extrazellulärer ATP-Konzentrationen, der dem inhibitorischen Effekt der Ektophosphorylierung von FAT/CD36 auf die Fettsäure-Aufnahme entgegenwirkt. / We investigated the correlation between the ecto-protein kinase A-mediated phosphorylation of the membrane-associated protein FAT/CD36 [Hatmi et al. 1996] and the initial cellular long chain fatty acid uptake. Under the conditions of FAT/CD36-ecto-phosphorylation, an inhibitory effect on the initial palmitate uptake of human platelets could be shown. This is the first time that a mechanism for the short-term regulation of protein-mediated long chain fatty acid uptake can be proposed. The isolation of morphologically and functionally intact resting human platelets and a method for measuring the initial palmitate uptake were established. The kinetics of palmitate uptake by human platelets were characterised and it was shown that a substantial fraction of initial palmitate uptake is protein-mediated. The ecto-protein kinase A-mediated, cAMP-dependent phosphorylation of FAT/CD36 as described by Hatmi and co-authors could be demonstrated under our experimental conditions. The ecto-phosphorylation of FAT/CD36 was paralleled by a significant impairment of the initial palmitate uptake. Maximum inhibition was achieved at 0,5 nM extracellular ATP, when the palmitate uptake was decreased to 72 % compared to control. The inhibition of palmitate uptake was abolished by co-incubation with the specific protein kinase A inhibitor peptide PKI 5-24 or with beta-gamma-methylene-ATP, and was fully reversible upon addition of alkaline phosphatase. The inhibitory effect of the ecto-phosphorylation on the initial palmitate uptake was significant at extracellular ATP concentrations between 10 pM and 15 nM. ATP concentrations over 15 nM reduced the effect and concentrations over 5 µM completely abolished it. We could exclude that the abolishment was caused by ATP-derivates. Our data point to a regulatory influence of higher ATP concentrations, that antagonises the inhibitory effect of the ecto-phosphorylation of FAT/CD36 on the initial palmitate uptake.
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The role of the LAMMER kinase Kns1 and the calcium/calmodulin-dependent kinase Cmk2 in the adaptation of Saccharomyces cerevisiae to alkaline pH stressMarshall, Maria Nieves Martinez 01 February 2013 (has links)
Die LAMMER-Kinasen sind Dual-Spezifität-Proteinkinasen, die durch das namensgebende einzigartige LAMMER-Motiv gekennzeichnet sind. Sie sind evolutionär hoch konserviert und in den meisten Eukaryonten vorhanden. Die vorliegende Arbeit stellt die erste funktionelle Charakterisierung eines bisher kaum erforschten Vertreters der LAMMER-Proteinkinase Familie Kns1 aus der Bäckerhefe dar. Phänotypische Analysen belegten eine entscheidende Rolle für Kns1 in der Regulation der Toleranz gegenüber basischem pH-Stress. Das Entfernen des KNS1 Gens führte zu einer gesteigerten Empfindlichkeit der Zellen gegenüber basischen Wachstumsbedingungen. Weitere Analysen zeigten, dass Kns1 neben der katalytischen Aktivität auch nicht-katalytischen Mechanismen zur Förderung des Zellwachstums unter alkalischem pH-Stress nutzt. Die Reinigung des Kns1 Proteins in voller Länge aus E. coli ermöglichte die Identifizierung von neun in vitro-Autophosphorylierungsstellen mittels Massenspektrometrie. Die Mutation von Thr562, eine Autophosphorylierungsstelle innerhalb des LAMMER-Motivs, zu Alanin ergab in vitro eine Kinase mit intrinsischer katalytischer Aktivität, die sich jedoch in vivo hauptsächlich wie die katalytisch inaktive Kns1-Mutante verhielt. Die Calcium/Calmodulin-abhängige Proteinkinase II Cmk2, die konstitutiv autokatalytische Eigenschaften besitzt, wurde früher als mögliches in vitro Substrat von Kns1 vorgeschlagen. In dieser Arbeit beweise ich durch Verwendung einer katalytisch inaktiven Cmk2-Mutante als Substrat, dass Kns1 Cmk2 in vitro phosphoryliert. Darüber hinaus zeige ich, dass Cmk2 die basische pH-Toleranz der Zellen beschränkt. Gestützt durch genetische Hinweise agieren beide Proteine gemeinsam bei der Regulation der alkalischen Stresstoleranz, wobei Kns1 möglicherweise Cmk2 herabreguliert. Zusammenfassend beschreibt diese Arbeit eine neue und entscheidende Rolle von Kns1 und Cmk2 bei der Anpassung der Hefe an alkalisches Milieu. / The LAMMER protein kinases, termed after a unique signature motif found in their catalytic domains, are an evolutionary conserved family of dual-specificity kinases that are present in most eukaryotes. Here I report the first functional characterization of one of the most unexplored members of the LAMMER family, the budding yeast Kns1. Phenotypic analysis uncovered a crucial role for Kns1 in the control of the yeast tolerance to high pH stress. Deletion of the KNS1 gene conferred high sensitivity to alkaline pH, whereas its overexpression increased tolerance to this stress. Further analysis established that Kns1 promotes growth under alkaline pH stress using not only its catalytic activity but also non-catalytic mechanisms. Large-scale purification of full-length Kns1 from E. coli allowed for the identification of nine in vitro autophosphorylation sites on Kns1 by mass spectrometry. Mutation of the threonine residue at position 562, an autophosphorylation site located within the LAMMER motif, to a non-phosphorylatable residue yielded a kinase that preserves intrinsic catalytic activity in vitro but mostly behaves like the catalytically inactive mutant in vivo. This finding showed the physiological importance of autophosphorylation site Thr562 in the regulation of Kns1 function. The protein Cmk2, a calcium/calmodulin-dependent protein kinase II with autocatalytic properties, has been previously proposed as a possible in vitro substrate for Kns1. Here I demonstrate that Kns1 phosphorylates Cmk2 in vitro using a catalytically inactive Cmk2 mutant as substrate and show that Cmk2 restricts alkaline tolerance. Genetic evidence suggested that both proteins act in concert on a common pathway, in which Kns1 may downregulate Cmk2 to confer alkaline tolerance. In conclusion, this thesis describes a novel and crucial role for Kns1 and its in vitro substrate Cmk2 in the adaptation of yeast to alkaline stress.
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Induction and Maintenance of Synaptic PlasticityGraupner, Michael 11 September 2008 (has links) (PDF)
Synaptic long-term modifications following neuronal activation are believed to be at the origin of learning and long-term memory. Recent experiments suggest that these long-term synaptic changes are all-or-none switch-like events between discrete states of a single synapse. The biochemical network involving calcium/calmodulin-dependent protein kinase II (CaMKII) and its regulating protein signaling cascade has been hypothesized to durably maintain the synaptic state in form of a bistable switch. Furthermore, it has been shown experimentally that CaMKII and associated proteins such as protein kinase A and calcineurin are necessary for the induction of long-lasting increases (long-term potentiation, LTP) and/or long-lasting decreases (long-term depression, LTD) of synaptic efficacy. However, the biochemical mechanisms by which experimental LTP/LTD protocols lead to corresponding transitions between the two states in realistic models of such networks are still unknown. We present a detailed biochemical model of the calcium/calmodulin-dependent autophosphorylation of CaMKII and the protein signaling cascade governing the dephosphorylation of CaMKII. As previously shown, two stable states of the CaMKII phosphorylation level exist at resting intracellular calcium concentrations. Repetitive high calcium levels switch the system from a weakly- to a highly phosphorylated state (LTP). We show that the reverse transition (LTD) can be mediated by elevated phosphatase activity at intermediate calcium levels. It is shown that the CaMKII kinase-phosphatase system can qualitatively reproduce plasticity results in response to spike-timing dependent plasticity (STDP) and presynaptic stimulation protocols. A reduced model based on the CaMKII system is used to elucidate which parameters control the synaptic plasticity outcomes in response to STDP protocols, and in particular how the plasticity results depend on the differential activation of phosphatase and kinase pathways and the level of noise in the calcium transients. Our results show that the protein network including CaMKII can account for (i) induction - through LTP/LTD-like transitions - and (ii) storage - due to its bistability - of synaptic changes. The model allows to link biochemical properties of the synapse with phenomenological 'learning rules' used by theoreticians in neural network studies.
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Inhibtion der Ca<sup>2+</sup>/Calmodulin-abhängigen Proteinkinase (CaMKII) verbessert die Kontratilität von terminal insuffizientem Myokard des Menschen / Inhibition of Ca<sup>2+</sup>/calmodulin-dependent protein kinase II (CaMKII) improves contractility in human end-stage failing myocardiumFluschnik, Nina 10 January 2012 (has links)
No description available.
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Mechanisms of posttetanic potentiation and its possible role in maturation of the calyx of Held synapse / Mechanisms of posttetanic potentiation and its possible role in maturation of the calyx of Held synapseKorogod, Natalya 25 April 2006 (has links)
No description available.
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Regulation of the anaphase promoting complex (APC/C) in the mitotic and meiotic cell cycle of Saccharomyces cerevisiae / Regulation des Anaphase promoting Komplex (APC/C) im mitotischen und meiotischen Zellzyklus von Saccharomyces cerevisiaeBolte, Melanie 22 January 2004 (has links)
No description available.
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Der PI3K/AKT/mTOR-Signalweg und die Produktion des Insulinähnlichen Wachstumsfaktorbindungsproteins-2 (IGFBP-2) in humanen AdipozytenWilhelm, Franziska Katharina 18 January 2017 (has links)
In den letzten Jahren wurde gezeigt, dass die Serumkonzentration des insulinähnlichen Wachstumsfaktorbindungsproteins-2 (IGFBP-2) bei Krebserkrankungen, die mit dem Verlust des Tumorsuppressorgens PTEN einhergehen, erhöht ist und daher möglicherweise einen Marker für den PTEN-Status und die Aktivität des PI3K/AKT/mTOR-Signalweges darstellt. Schmid et al. haben 2014 einen Patienten mit PTEN-Hamartom-Tumor-Syndrom (PHTS) mit einer heterozygoten PTEN-Keimbahndeletion und massiver Lipomatose beschrieben, bei dem erhöhte IGFBP-2 Serumspiegel gemessen wurden. Ziel dieser Arbeit war es zu analysieren, ob PTEN-defiziente Lipomzellen des Patienten im Vergleich zu Kontrollfettzellen mehr IGFBP-2 produzieren, sowie den Einfluss verschiedener pharmakologischer Inhibitoren des AKT/PI3K/mTOR - und des MAPK- Signalwegs auf die IGFBP-2 Produktion zu untersuchen. In der PTEN-defizienten Lipomzellkultur, gewonnen aus reseziertem Lipomgewebe des Patienten, wurden vergleichbare Mengen an IGFBP-2 wie in den nicht PTEN-defizienten Kontrollzellen gefunden. Die pharmakologische Hemmung der PI3K und AKT bewirkten eine signifikante Senkung der IGFBP-2 Expression und Sekretion, wohingegen sich bei Hemmung der MEK und des mTORC1 keine Effekte zeigten. Diese Ergebnisse weisen darauf hin, dass eine heterozygote PTEN-Deletion in Lipomzellen nicht zu einer erhöhten IGFBP-2 Produktion führt und daher die erhöhten Serumspiegel des Patienten nicht darauf zurückzuführen sind. Des Weiteren bestätigen die in vitro Ergebnisse die klinische Beobachtung, dass unter der Therapie mit dem mTORC1-Inhibitor Rapamycin die IGFBP-2 Serumspiegel des Patienten nicht zurückgingen. Möglicherweise stellt IGFBP-2 jedoch einen geeigneten Verlaufsmarker für eine Therapie mit PI3K- oder AKT-Inhibitoren dar.
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