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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
11

O envolvimento da proteína fosfatase 2A e do sistema glutamatérgico em processos neurodegenerativos relacionados à doença de Alzheimer : mecanismos e biomarcadores de imagem / The involvement of protein phosphatase 2A and glutamatergic system in neurodegenerative processes related to Alzheimer’s disease : mechanisms and imaging biomarkers

Zimmer, Eduardo Rigon January 2015 (has links)
A doença de Alzheimer (DA) é uma patologia neurodegenerativa progressiva e a forma de demência mais prevalente no mundo. As alterações fisiopatológicas da DA têm sido associadas a dois marcadores neuropatológicos clássicos: a deposição de placas de β- amilóide e a formação de emaranhados neurofibrilares da proteína tau hiperfosforilada. Porém, devido a complexidade da DA, outros mecanismos têm sido propostos como coadjuvantes no processo neurodegenerativo, entre eles eventos neuroinflamatórios, a quebra da homeostasia de sistemas de neurotransmissão e disfunção sináptica. Esta pletora de eventos patológicos parece preceder a fase de demência por um longo período onde a doença age de forma silenciosa, ou seja, onde não existem evidências sintomatológicas. Na presente tese, avançamos no entendimento de vias de sinalização associadas com a hipersforforilação da proteína tau envolvendo a disfunção da proteína fosfatase 2A e neurotoxicidade do sistema glutamatérgico. Além disso, avaliamos os radiofármacos de tomografia de emissão de pósitrons (PET) disponíveis para visualização in vivo e não invasiva da fisiopatologia da DA. Finalmente, avaliamos um novo biomarcador de PET, o [11C]ABP688, para visualizar flutuações no sistema glutamatérgico e avançamos no entendimento do impacto das células gliais no sinal do PET [18F]FDG, o radiofármaco mais utilizado na clínica atualmente para visualizar metabolismo de glicose cerebral. O [11C]ABP688 pode ser diretamente incluído em estudos clínicos e a reconceptualização do [18F]FDG proposta nesta tese pode alterar a maneira atual como vemos o metabolismo de glicose na DA e em outras doenças neurodegenerativas. Finalmente, nesta tese, avançamos em termos de mecanismos, e no contexto da busca por um diagnóstico precoce e acurado da DA. / Alzheimer's disease (AD) is a progressive neurodegenerative disorder and the most prevalent cause of dementia worldwide. The AD pathophysiological features have been associated to two main classic neuropathological markers: depositon of β-amyloid plaques and formation of neurofibrillary tangles of hyperphosphorylated tau. Due to AD complexity, however, additional mechanisms have been proposed as contributors to the neurodegenerative process, such as neuroinflammatory changes, altered neurotransmission, and synaptic dysfunction. These pathological events seem to precede the dementia phase by many years, resulting in a long silent period, i.e., a preclinical phase. In this thesis, we advanced in the understanding of signaling pathways associated with tau hyperphosphorylation, which includes dysfunction of protein phosphatase 2A (PP2A) and glutamatergic neurotoxicity. Furthermore, we underscored radiopharmaceuticals currently available for imaging AD pathophysiology in vivo and non-invasively with positron emission tomography (PET). Finally, we evaluated a new PET biomarker, [11C]ABP688, for visualizing glutamatergic fluctuations and advanced in the understating of how glial cells contribute to the [18F]FDG signal, the widely used radiopharmaceutical in clinical settings for visualizing cerebral glucose metabolism. Our findings have high translational value and direct impact in clinical settings, which can potentially alter the way we interpret glucose metabolism in AD and other neurodegenerative disorders. In summary, in this thesis, we have advanced in terms of molecular mechanisms, and in the use of PET biomarkers toward an early and accurate diagnosis of AD.
12

O envolvimento da proteína fosfatase 2A e do sistema glutamatérgico em processos neurodegenerativos relacionados à doença de Alzheimer : mecanismos e biomarcadores de imagem / The involvement of protein phosphatase 2A and glutamatergic system in neurodegenerative processes related to Alzheimer’s disease : mechanisms and imaging biomarkers

Zimmer, Eduardo Rigon January 2015 (has links)
A doença de Alzheimer (DA) é uma patologia neurodegenerativa progressiva e a forma de demência mais prevalente no mundo. As alterações fisiopatológicas da DA têm sido associadas a dois marcadores neuropatológicos clássicos: a deposição de placas de β- amilóide e a formação de emaranhados neurofibrilares da proteína tau hiperfosforilada. Porém, devido a complexidade da DA, outros mecanismos têm sido propostos como coadjuvantes no processo neurodegenerativo, entre eles eventos neuroinflamatórios, a quebra da homeostasia de sistemas de neurotransmissão e disfunção sináptica. Esta pletora de eventos patológicos parece preceder a fase de demência por um longo período onde a doença age de forma silenciosa, ou seja, onde não existem evidências sintomatológicas. Na presente tese, avançamos no entendimento de vias de sinalização associadas com a hipersforforilação da proteína tau envolvendo a disfunção da proteína fosfatase 2A e neurotoxicidade do sistema glutamatérgico. Além disso, avaliamos os radiofármacos de tomografia de emissão de pósitrons (PET) disponíveis para visualização in vivo e não invasiva da fisiopatologia da DA. Finalmente, avaliamos um novo biomarcador de PET, o [11C]ABP688, para visualizar flutuações no sistema glutamatérgico e avançamos no entendimento do impacto das células gliais no sinal do PET [18F]FDG, o radiofármaco mais utilizado na clínica atualmente para visualizar metabolismo de glicose cerebral. O [11C]ABP688 pode ser diretamente incluído em estudos clínicos e a reconceptualização do [18F]FDG proposta nesta tese pode alterar a maneira atual como vemos o metabolismo de glicose na DA e em outras doenças neurodegenerativas. Finalmente, nesta tese, avançamos em termos de mecanismos, e no contexto da busca por um diagnóstico precoce e acurado da DA. / Alzheimer's disease (AD) is a progressive neurodegenerative disorder and the most prevalent cause of dementia worldwide. The AD pathophysiological features have been associated to two main classic neuropathological markers: depositon of β-amyloid plaques and formation of neurofibrillary tangles of hyperphosphorylated tau. Due to AD complexity, however, additional mechanisms have been proposed as contributors to the neurodegenerative process, such as neuroinflammatory changes, altered neurotransmission, and synaptic dysfunction. These pathological events seem to precede the dementia phase by many years, resulting in a long silent period, i.e., a preclinical phase. In this thesis, we advanced in the understanding of signaling pathways associated with tau hyperphosphorylation, which includes dysfunction of protein phosphatase 2A (PP2A) and glutamatergic neurotoxicity. Furthermore, we underscored radiopharmaceuticals currently available for imaging AD pathophysiology in vivo and non-invasively with positron emission tomography (PET). Finally, we evaluated a new PET biomarker, [11C]ABP688, for visualizing glutamatergic fluctuations and advanced in the understating of how glial cells contribute to the [18F]FDG signal, the widely used radiopharmaceutical in clinical settings for visualizing cerebral glucose metabolism. Our findings have high translational value and direct impact in clinical settings, which can potentially alter the way we interpret glucose metabolism in AD and other neurodegenerative disorders. In summary, in this thesis, we have advanced in terms of molecular mechanisms, and in the use of PET biomarkers toward an early and accurate diagnosis of AD.
13

O envolvimento da proteína fosfatase 2A e do sistema glutamatérgico em processos neurodegenerativos relacionados à doença de Alzheimer : mecanismos e biomarcadores de imagem / The involvement of protein phosphatase 2A and glutamatergic system in neurodegenerative processes related to Alzheimer’s disease : mechanisms and imaging biomarkers

Zimmer, Eduardo Rigon January 2015 (has links)
A doença de Alzheimer (DA) é uma patologia neurodegenerativa progressiva e a forma de demência mais prevalente no mundo. As alterações fisiopatológicas da DA têm sido associadas a dois marcadores neuropatológicos clássicos: a deposição de placas de β- amilóide e a formação de emaranhados neurofibrilares da proteína tau hiperfosforilada. Porém, devido a complexidade da DA, outros mecanismos têm sido propostos como coadjuvantes no processo neurodegenerativo, entre eles eventos neuroinflamatórios, a quebra da homeostasia de sistemas de neurotransmissão e disfunção sináptica. Esta pletora de eventos patológicos parece preceder a fase de demência por um longo período onde a doença age de forma silenciosa, ou seja, onde não existem evidências sintomatológicas. Na presente tese, avançamos no entendimento de vias de sinalização associadas com a hipersforforilação da proteína tau envolvendo a disfunção da proteína fosfatase 2A e neurotoxicidade do sistema glutamatérgico. Além disso, avaliamos os radiofármacos de tomografia de emissão de pósitrons (PET) disponíveis para visualização in vivo e não invasiva da fisiopatologia da DA. Finalmente, avaliamos um novo biomarcador de PET, o [11C]ABP688, para visualizar flutuações no sistema glutamatérgico e avançamos no entendimento do impacto das células gliais no sinal do PET [18F]FDG, o radiofármaco mais utilizado na clínica atualmente para visualizar metabolismo de glicose cerebral. O [11C]ABP688 pode ser diretamente incluído em estudos clínicos e a reconceptualização do [18F]FDG proposta nesta tese pode alterar a maneira atual como vemos o metabolismo de glicose na DA e em outras doenças neurodegenerativas. Finalmente, nesta tese, avançamos em termos de mecanismos, e no contexto da busca por um diagnóstico precoce e acurado da DA. / Alzheimer's disease (AD) is a progressive neurodegenerative disorder and the most prevalent cause of dementia worldwide. The AD pathophysiological features have been associated to two main classic neuropathological markers: depositon of β-amyloid plaques and formation of neurofibrillary tangles of hyperphosphorylated tau. Due to AD complexity, however, additional mechanisms have been proposed as contributors to the neurodegenerative process, such as neuroinflammatory changes, altered neurotransmission, and synaptic dysfunction. These pathological events seem to precede the dementia phase by many years, resulting in a long silent period, i.e., a preclinical phase. In this thesis, we advanced in the understanding of signaling pathways associated with tau hyperphosphorylation, which includes dysfunction of protein phosphatase 2A (PP2A) and glutamatergic neurotoxicity. Furthermore, we underscored radiopharmaceuticals currently available for imaging AD pathophysiology in vivo and non-invasively with positron emission tomography (PET). Finally, we evaluated a new PET biomarker, [11C]ABP688, for visualizing glutamatergic fluctuations and advanced in the understating of how glial cells contribute to the [18F]FDG signal, the widely used radiopharmaceutical in clinical settings for visualizing cerebral glucose metabolism. Our findings have high translational value and direct impact in clinical settings, which can potentially alter the way we interpret glucose metabolism in AD and other neurodegenerative disorders. In summary, in this thesis, we have advanced in terms of molecular mechanisms, and in the use of PET biomarkers toward an early and accurate diagnosis of AD.
14

Caracterização das proteinas TIPRL e alfa4, reguladores de fosfatases 2A / Characterization of the type 2A phosphatase regulatory protein, TIPRL and alpha4

Smetana, Juliana Helena Costa 13 August 2018 (has links)
Orientador: Nilson Ivo Tonin Zanchin / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-13T09:08:00Z (GMT). No. of bitstreams: 1 Smetana_JulianaHelenaCosta_D.pdf: 8660811 bytes, checksum: cb33e97d4c49fdce1e29094a2f6089cc (MD5) Previous issue date: 2009 / Resumo: As células respondem constantemente a uma enorme variedade de estímulos, que são interpretados e integrados por meio de redes de sinalização, dando origem a uma resposta biológica. Defeitos nesses circuitos são a causa de diversas doenças, incluindo muitos, se não todos os tipos de câncer. As fosfatases, enzimas que removem grupamentos fosfato dos substratos de quinases, dependem principalmente de subunidades regulatórias para definir sua especificidade. As fosfatases do tipo 2A constituem a subfamília PPP, que é formada por PP2A, PP4 e PP6. PP2A é a principal fosfatase solúvel de fosfosserina e fosfotreonina em células animais e é encontrada predominantemente como uma holoenzima formada por uma subunidade catalítica (C), uma subunidade regulatória (B, B', B'' ou B''') e uma de ancoragem (PR65/A). Em levedura, as fosfatases 2A desempenham um importante papel na via da quinase TOR, o que ocorre por meio da proteína essencial Tap42. A proteína Tip41 foi identificada como um parceiro de interação de Tap42 e regulador da via da quinase TOR em levedura. A homóloga de Tap42 em mamíferos, chamada de a4, está envolvida na regulação de diversos processos celulares, como diferenciação, desenvolvimento, migração celular e apoptose, por meio de seu papel conservado de regulador de fosfatases 2A. A homóloga em mamíferos de Tip41, chamada TIPRL, é uma proteína ainda pouco caracterizada. Este trabalho teve como objetivo analisar a função das proteínas a4 e TIPRL humanas e esclarecer seu papel na regulação de fosfatases 2A. A caracterização estrutural de a4 e Tap42, usando dados de SAXS, dicroísmo circular e proteólise limitada, mostrou que essas proteínas apresentam um domínio N-terminal compacto formado por a-hélices e um domínio C-terminal desestruturado. Em uma triagem de interações com a proteína TIPRL humana, identificamos as fosfatases PP2Ac, PP4c e PP6c como seus parceiros de interação, assim como os fatores de transcrição MafB e TAF10. Ao contrário do esperado a partir do modelo de levedura, a4 e TIPRL não interagem diretamente, mas formam um complexo ternário com PP2Ac. Uma triagem de substratos de fosfatases 2A regulador por TIPRL identificou os fatores de splicing SF2/ASF e SF2p32. Nossos resultados sugerem um modelo estrutural para a regulação das fosfatases 2A por a4 e mostram que TIPRL é um novo regulador comum dessas fosfatases com funções na regulação da expressão gênica. / Abstract: Cells respond constantly to a variety of stimuli, which are interpreted and integrated through signaling networks, giving rise to biological responses. Defects in this circuitry are a cause of many diseases, including cancer. Protein phosphatases are enzymes which remove phosphate groups from kinase substrates, relying mainly on regulatory subunits for their substrate specificity. Type 2A phosphatases belong to the PPP subfamily, which is formed by PP2A, PP4 and PP6. PP2A is the major soluble serine/threonine phosphatase in animal cells and is found predominantly as a heterotrimer composed of a catalytic (C), a regulatory (B, B', B'' or B''') and a scaffold (PR65/A) subunit. Type 2A phosphatases play a major role in the yeast TOR signaling pathway through their interaction with the essential protein Tap42. Tip41 was identified as a Tap42 interacting protein and regulator of the TOR pathway. a4, the mammalian orthologue of Tap42, regulates many cellular processes such as differentiation, development, cell migration and apoptosis as a conserved type 2A phosphatase regulator. TIPRL, the mammalian orthologue of Tip41, is still poorly characterized. The objective of the present work was to analyse the function of a4 and TIPRL and improve the understanding of their role as type 2A phosphatase regulators. The structural characterization of a4 using SAXS analyses, circular dichroism and limited proteolysis, showed that these proteins are formed by an a-helical N-terminal domain and an unfolded C-terminal domain. A screen for TIPRL interacting proteins identified PP2Ac, PP4c and PP6c and also the transcription factors MafB and TAF10. Unlike their yeast conterparts, a4 and TIPRL do not interact directly, but rather form a ternary complex with PP2A. A search for type 2A phosphatase substrates regulated by TIPRL identified the splicing factor SF2/ASF and its regulatory protein SF2p32. Our results suggest a structural model for the regulation of type 2A phosphatases by a4 and show that TIPRL is a novel common regulator of these phosphatases which functions in regulation of gene expression. / Doutorado / Genetica Animal e Evolução / Doutor em Genetica e Biologia Molecular
15

The yeast Rts1, a subunit of PP2A phosphatase, is involved in stress response

Eshrif, Abdelmolez 12 1900 (has links)
No description available.
16

Investigation of Protein Phosphatase 2A A-alpha Subunit Mutation as a Disease Driver in High-Grade Endometrial Carcinoma

Taylor, Sarah Elizabeth January 2019 (has links)
No description available.
17

Protein phosphatase 2A (PP2A) holoenzymes regulate death associated protein kinase (DAPK) in ceramide-induced anoikis

Widau, Ryan Cole 03 May 2010 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Modulation of sphingolipid-induced apoptosis is a potential mechanism to enhance the effectiveness of chemotherapeutic drugs. Ceramide is a pleiotropic, sphingolipid produced by cells in response to inflammatory cytokines, chemotherapeutic drugs and ionizing radiation. Ceramide is a potent activator of protein phosphatases, including protein phosphatase 2A (PP2A) leading to dephosphorylation of substrates important in regulating mitochondrial dysfunction and apoptosis. Previous studies demonstrated that death associated protein kinase (DAPK) plays a role in ceramide-induced apoptosis via an unknown mechanism. The tumor suppressor DAPK is a calcium/calmodulin regulated serine/threonine kinase with an important role in regulating cytoskeletal dynamics. Auto-phosphorylation within the calmodulin-binding domain at serine308 inhibits DAPK catalytic activity. Dephosphorylation of serine308 by a hitherto unknown phosphatase enhances kinase activity and proteasomal mediated degradation of DAPK. In these studies, using a tandem affinity purification procedure coupled to LC-MS/MS, we have identified two holoenzyme forms of PP2A as DAPK interacting proteins. These phosphatase holoenzymes dephosphorylate DAPK at Serine308 in vitro and in vivo resulting in enhanced kinase activity of DAPK. The enzymatic activity of PP2A also negatively regulates DAPK protein levels by enhancing proteasomal-mediated degradation of the kinase, as a means to attenuate prolonged kinase activation. These studies also demonstrate that ceramide causes a caspase-independent cell detachment in HeLa cells, a human cervical carcinoma cell line. Subsequent to detachment, these cells underwent caspase-dependent apoptosis due to lack of adhesion, termed anoikis. Overexpression of wild type DAPK induced cell rounding and detachment similar to cells treated with ceramide; however, this effect was not observed following expression of a phosphorylation mutant, S308E DAPK. Finally, the endogenous interaction of DAPK and PP2A was determined to be required for ceramide-induced cell detachment and anoikis. Together these studies have provided exciting and essential new data regarding the mechanisms of cell adhesion and anoikis. These results define a novel cellular pathway initiated by ceramide-mediated activation of PP2A and DAPK to regulate inside-out signaling and promote anoikis.
18

DIRECT PP2A ACTIVATION FOR THE TREATMENT OF KRAS- AND EGFR-DRIVEN LUNG ADENOCARCINOMA

Tohme, Rita 04 June 2018 (has links)
No description available.
19

Analysis of new genes controlling Drosophila melanogaster rest-activity rhythms / Analyse de nouveaux gènes impliqués dans le contrôle des rythmes veille-sommeil chez Drosophila melanogaster

Andreazza, Simonetta 13 December 2013 (has links)
Les mécanismes moléculaires contrôlant les rythmes circadiens sont conservés parmi les organismes des différents règnes (plantes, animaux et champignons). Ils se composent de boucles de rétroaction où un complexe d’activation transcriptionnelle, l’hétérodimère CLK/CYC chez la drosophile, entraîne l'expression des répresseurs de son activité, les gènes et protéines PER et TIM chez la mouche. De manière importante, la période de l'oscillateur dépend en grande partie par des mécanismes post-transcriptionnels qui régulent l’accumulation et l'activité des composantes positifs et négatifs de la boucle. Bien que de nombreux partenaires d'interaction modifiant les composants d'horloge de base ont déjà pu être isolés, le schéma reste encore incomplet. Dans le cadre de la recherche de nouveaux composants de cette horloge, nous avons réalisé un crible comportemental basé sur l'expression ciblée de transgènes ARNi dirigés contre la moitié du génome de Drosophila melanogaster. Cinquante-quatre nouveaux gènes putatifs ont pu être identifiés. Au cours de ce travail, j'ai étudié le rôle de deux d’entre eux, sélectionnés pour les forts défauts comportementaux de l'expression de leur transgène ARNi. Le gène CG12082 de la drosophile est l’orthologue de l’Ubiquitin-specific protéase 5 (USP5) chez l’homme. La dérégulation d’Usp5 retarde les oscillations de la protéine PER dans les neurones d'horloge et allonge la période d'activité locomotrice des mouches. Chez les mouches ARNi Usp5, des formes à haut poids moléculaire des protéines PER et TIM s'accumulent pendant le matin, alors qu’elles sont normalement dégradées chez les contrôles. On a pu montrer que Usp5 participe directement à la dégradation de la protéine PER, indépendamment de TIM. En accord avec le rôle décrit pour l’orthologue humaine, Usp5 serait susceptible de contrôler la dégradation des protéines par son activité de démontage des chaînes libres de polyubiquitine présents dans la cellule, qui peuvent entrer en compétition avec les protéines ubiquitinylées pour la reconnaissance au niveau du protéasome, bloquant leur dégradation. La majorité des travaux ont porté sur un gène isolé au cours de notre crible, Strip, dont les fonctions étaient encore inconnues. Strip interagit avec Cka, une nouvelle sous-unité régulatrice de l’enzyme phosphatase PP2A. La dérégulation à la fois de Strip et/ou de Cka amène à des phénotypes comportementaux de période longue. D’un point de vue moléculaire, des formes hyper-phosphorylées de la protéine CLK s’accumulent dans la matinée quand Cka et/ou Strip sont perturbées. La dérégulation des activités générales de PP2A produit également une hyper-phosphorylation de CLK le matin, indiquant que, grâce à Cka/Strip, les complexes PP2A contrôlent la déphosphorylation de CLK à la fin du cycle. Il est connu que les formes hyper-phosphorylés de CLK sont transcriptionnellement inactives. En effet, la transcription des gènes tim et vrille, cibles de CLK, est fortement réduite dans les mouches ARNi Cka. En plus de PP2A/Cka, des complexes PP2A contenant une autre sous-unité régulatrice, Wdb, ont été montré pour déstabiliser CLK en culture des cellules (Kim et Edery, 2006). Nous montrons que la dérégulation de Wdb affecte la stabilité du CLK également dans la mouche adulte, sans toutefois induire aucun effet apparent sur sa phosphorylation. En conclusion, deux complexes PP2A différents agissent sur la protéine CLK : le complexe PP2A/Cka/Strip contrôle la déphosphorylation de CLK et sa réactivation, tandis que PP2A/Wdb affecte la stabilité de CLK indépendamment ou après PP2A/Cka. Ces résultats enrichissent l’étude de la régulation post-traductionnelle de la protéine CLK, qui était largement mal connue.Pour conclure, cette étude a permis de décrire deux nouveaux composants de la boucle moléculaire qui contrôle les rythmes circadiens chez la mouche du vinaigre, Drosophila melanogaster. / The molecular mechanism underlying circadian rhythms is conserved among organisms and consists of feedback loops where a transcriptional activating complex (the CLOCK (CLK)/CYCLE (CYC) heterodimer in Drosophila) drives the expression of the repressors of its activity (the period (per) and timeless (tim) genes and proteins in Drosophila). Importantly, the pace of the oscillator largely depends on post-transcriptional mechanisms that regulate the accumulation and activity of both the positive and negative components of the loop. A number of interacting partners that modify core clock components have already been isolated, but more are expected. Looking for new clock components, we set up a behavioral screen based on targeted expression of RNAi transgenes directed to half of the Drosophila genome. 54 putative new clock genes have been identified. Among them, some were independently reported to function within the fruit fly molecular clock, thus validating the screen. In this work, I investigated the circadian role of additional “positive” genes, selected for the strong behavioral defect induced by the expression of the corresponding RNAi. The CG12082 gene codes for the fruit fly ortholog of the human Ubiquitin-specific protease 5 (USP5). Downregulation of USP5 in clock cells lengthens the period of locomotor activity of flies as well as PER protein oscillations in clock neurons. High molecular weight forms of PER and TIM proteins accumulate during the morning after USP5 knockdown, while these forms are degraded in controls. In addition, TIM is not stabilized in the absence of PER, while PER still accumulate in the absence of TIM. Therefore, USP5 directly participates in the degradation of the PER protein and, later, of the TIM protein at the end of the cycle. Being a deubiquitinylase enzyme, USP5 may directly deubiquitinate PER. However, accordingly to the role described for the human ortholog, USP5 likely controls protein degradation through the disassembling of the unanchored polyubiquitin chains present in the cell that could compete with ubiquitinated-PER for proteasome recognition and subsequent breakdown.The majority of the work has focused on an unknown gene isolated in the screen, that, accordingly to the human homolog, we named STRIP. We show that STRIP interacts with Connector of Kinase to AP-1 (CKA), a novel regulatory subunit for the PP2A phosphatase holoenzyme, both in insect S2 cells and in fly head extracts. Downregulation of both STRIP and/or CKA causes long-period behavioral phenotypes and high molecular weight forms of the CLK protein to accumulate in the morning. Perturbation of general PP2A activities also produces hyper-phosphorylated CLK in the morning indicating that, through CKA/STRIP, PP2A complexes controls CLK dephosphorylation at the end of the cycle. Hyper-phosphorylated CLK forms are transcriptionally inactive. Accordingly, transcription of the tim and vrille (vri) CLK targets is strongly reduced in Cka-RNAi fly head extracts. PP2A complexes containing the Widerborst (WDB) regulatory subunits were already shown to affect CLK stability in insect S2 cells (Kim and Edery, 2006). We show that WDB downregulation also affects the stability of CLK in fly head extracts, but has no apparent effects on CLK phosphorylation. Therefore, we could describe two different PP2A complexes acting on the CLK protein: PP2A/CKA/STRIP complex controls CLK dephosphorylation and reactivation, while PP2A/WDB affects CLK stability independently or after PP2A/CKA functions. Moreover, STRIP, but not CKA, downregulation affects the stability of PER, indicating that STRIP possesses some functions unrelated to CKA. In conclusion, this work has allowed the isolation of new components of the Drosophila molecular clock. In particular, we give evidence for a double role for the PP2A phosphatase in modulating the activity and stability of the CLK protein, the regulation of which is not well understood yet.
20

Leveraging Small Molecule Activators of Protein Phosphatase 2A (PP2A) toElucidate PP2As Role in Regulating DNA Replication and Apoptosis

Perl, Abbey Leigh 28 January 2020 (has links)
No description available.

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