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Biochemical and Structural Studies on the Adaptor Protein p130CasNasertorabi, Fariborz January 2005 (has links)
Crk associated substrate (Cas) is an adaptor protein that becomes phosphorylated upon integrin signaling and influences regulation of cell processes such as migration, proliferation and survival. It consists of multiple domains and regions that can interact with several signaling proteins involved in different signaling pathways. Cas was first discovered as a highly phosphorylated protein in v-Src and v-Crk transformed cells, showing involvement of this protein in cell transformation High level of Breast cancer antiestrogen resistance protein (BCAR-1), a homologue to Cas has shown to correlate with rapid reoccurrence of breast cancer and also create resistance towards Tamoxifen, the widely used medicine for receptor positive breast cancer patients. We have defined boundaries of two regions of Cas termed serine rich region (SRR) and Src binding domain (SBD) respectively and have isolated these segments for biochemical and structural studies. The structure of the serine rich part of Cas has been determined by NMR spectroscopy and reveals a four-helix bundle with unusually long loops. The 14-3-3 protein binds to Cas in a phospho-serine dependent manner and our study suggests that the binding site is located between two helices. The SH2-SH3 domain of a Src family kinase, Lck has also been crystallized in complex with a nine residue long peptide corresponding to the region in Cas that binds to SH2 domains. The structure of this complex has been solved at 2.7Å and shows that Cas binds Src family kinases (SFK) with high affinity suggesting a specific interaction between these two molecules. The biochemical studies on the specific binding site of these molecules show that SFK can bind to any of the phosphorylated tyrosines on the SH2 binding domain of Cas and only one phospho-tyrosine is enough to establish the binding. This binding assay does also indicate that SH3 binding domain of Cas is not essential for SFK binding.
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Cascades physiopathologiques dans la maladie de Sanfilippo B / Pathophysiological cascades of Sanfilippo B diseaseBruyere, Julie 22 October 2012 (has links)
La mucopolysaccharidose de type IIIB (MPSIIIB), ou maladie de Sanfilippo B, est une maladie de surcharge lysosomale caractérisée par des atteintes neurologiques. Cette maladie génétique rare est causée par la déficience en a-N-acétylglucosaminidase (NAGLU), une enzyme nécessaire pour la dégradation des héparanes sulfates (HS). La dégradation incomplète des HS cause l’accumulation de saccharides d’HS dans les lysosomes et à la surface des cellules. Mais la cascade physiopathologique induite par ces saccharides n’est pour l’instant pas connue. D’une part, ces recherches fournissent des preuves que la communication avec l’environnement des cellules neurales déficientes en NAGLU est altérée. En effet, l’intégrine ß1 et ses effecteurs sont suractivés et recrutés au niveau des plaques d’adhérence dans des astrocytes déficients. Les comportements cellulaires dépendants des intégrines, tels que la polarisation et la migration, sont également altérés. Ces phénotypes sont restaurés par l’apport de l’enzyme déficiente. Cette restauration indique que l’accumulation de saccharides d’HS provoque l’activation de la signalisation des intégrines, et perturbe la polarisation et la migration des cellules neurales. L’ajout de saccharides d’HS purifiés sur des cellules neurales normales confirme que les saccharides d’HS extracellulaires activent des composants des plaques d’adhérence. D’autre part, l’étude d’un modèle cellulaire humain, dont l’expression de NAGLU a été inhibée par shRNA, a montré que l’accumulation de vésicules de stockage caractéristiques de la maladie est causée, entre autre, par une déformation de l’appareil de Golgi et la surexpression de GM130. Ces phénotypes sont également observés dans les neurones atteints. Ils s’accompagnent d’une augmentation de la stabilité et de la nucléation des microtubules, au niveau de l’appareil de Golgi. Les défauts de communication entre la cellule malade et son environnement semblent donc modifier la dynamique et la structure cellulaire. Nous présumons que les mécanismes physiopathologiques déchiffrés en culture sont reliés à la neuropathologie de la MPSIIIB. En perturbant la perception de l’environnement cellulaire, la polarité, la migration, et la pousse neuritique, les saccharides d’HS accumulés dans les tissus cérébraux malades, affectent probablement divers mécanismes clefs de la maturation corticale. / Mucopolysaccharidosis type IIIB (Sanfilippo B disease) is a lysosomal storage disease characterized by severe neurological manifestations in children. This rare monogenic disease is caused by a-Nacetylglucosaminidase (NAGLU) deficiency, a lysosomal hydrolase necessary for heparan sulfate (HS) degradation. This deficiency leads to the accumulation of HS saccharides. Mechanisms mediating HS saccharides deleterious effects on brain cells are not well understood. This research provides evidences that neural cell sensing of environment is altered in MPSIIIB cells. Integrins and focal adhesion components are over-recruited and over-activated in deficient mouse astrocytes. Consistently, integrin-dependant cell behavior such as cell polarization and directed migration were defective in affected astrocytes and neural stem cells. HS saccharide clearance, by NAGLU gene transfer, rescues a normal phenotype suggesting that HS saccharides induce focal adhesion formation. Addition of purified HS saccharides on normal astrocytes confirms that extracellular HS saccharides can activate the recruitment of focal adhesion components and provides an in vitro assay to decipher the saccharide code of HS. Otherwise, investigations performed on HeLa cell model, in which NAGLU expression was inhibited by shRNA, showed that accumulation of intracellular storage vesicles, a hallmark of the disease, is due over expression of a cis-Golgi protein. This affects the Golgi morphology and microtubule nucleation and stability. It seems that alterations of environment cell sensing and downstream signaling also modify the dynamic and the structure of cells. We assume that mechanisms deciphered in cell cultures are related to MPSIIIB neuropathology. By affecting cell perception of environmental cues, cell polarity, cell migration and neurite outgrowth, HS saccharides, which accumulate in brain tissues defective for a HS degradation enzyme, likely affect various processes important for accurate cortical maturation.
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Deciphering the Mechanisms of AMPK Activation upon Anchorage- DeprivationSundararaman, Ananthalakshmy January 2016 (has links) (PDF)
AMP-activated protein kinase (AMPK) is a key regulator of energy homeostasis in cells. It has been implicated as a therapeutic target for various metabolic diseases like type II diabetes and obesity. However, its role in cancer is context-dependent and therefore warrants further studies to explore its possible use as a therapeutic target. AMPK can either promote or retard the growth of cancer cells depending on other cues and stresses in the milieu of the cancer cells. This study aims to understand AMPK signalling in response to extracellular cues of matrix deprivation and matrix stiffness that are important determinants of metastasis.
1) Calcium-Oxidant Signalling Network Regulates AMPK Activation upon Matrix Deprivation.
Recent work from our lab, as well as others, has identified a novel role for the cellular energy sensor AMP-activated protein kinase in epithelial cancer cell survival under matrix deprivation. However, the molecular mechanisms that activate AMPK upon matrix-detachment remain unexplored. In this study, we show that AMPK activation is a rapid and sustained phenomenon upon matrix deprivation, while re-attachment to the matrix leads to its dephosphorylating and inactivation. Since matrix-detachment leads to loss of integrin signalling, we investigate whether integrin signalling negatively regulates AMPK activation. However, modulation of FAK or Src, the major downstream components of integrin signalling, fails to cause a corresponding change in AMPK signalling. Further investigations reveal that the upstream AMPK kinases, LKB1 and CaMKKβ, contribute to AMPK activation upon detachment. Additionally, we show LKB1 phosphorylation and cytosolic translocation upon matrix deprivation, which might also contribute to AMPK activation. In LKB1-deficient cells, we find AMPK activation to be predominantly dependent on Caskβ. We observe no change in ATP levels under detached conditions at early time points suggesting that rapid AMPK activation upon detachment is not triggered by energy stress. We demonstrate that matrix deprivation leads to a spike in intracellular calcium as well as oxidant signalling and both these
intracellular messengers contribute to rapid AMPK activation upon detachment. We further show that ER calcium release induced store-operated calcium entry (SOCE) contributes to intracellular calcium increase, leading to ROS production, and AMPK activation. We additionally show that the LKB1/CaMKK-AMPK axis and intracellular calcium levels play a critical role in anchorage-independent cancer sphere formation. We find a significant increase in LKB1 as well as pACC levels in breast tumour tissues in comparison to normal tissues. Further, we observe a significant correlation between LKB1 and pACC levels in breast tumour tissues suggesting that LKB1-AMPK signaling pathway is active in vivo in breast cancers. Thus, the Ca2+/ROS triggered LKB1/CaMKK-AMPK signalling cascade may provide a quick, adaptable switch to promote survival of metastasising cancer cells.
2) Extracellular Matrix Stiffness Regulates Stemless through AMPK.
Cancer cells experience changes in extracellular matrix stiffness during cancer progression. However, the signalling pathways utilised in sensing matrix stiffness are poorly understood. In this study, we identify AMPK pathway as a possible mechanosensory pathway in response to matrix stiffness. AMPK activity, as measured by downstream target phosphorylation, is found to be higher in soft matrix conditions. We additionally show that compared to stiff matrices, soft matrices increase stemless properties, as evidenced by the increased expression of stemless markers, which is dependent on AMPK activity. Thus, we elucidate a novel mechanotransduction pathway triggered by matrix stiffness that contributes to stemness of cancer cells by regulating AMPK activity.
Taken together, our study identifies a novel calcium-oxidant signaling network in the rapid modulation of AMPK signaling in the context of matrix detachment. This pathway is especially relevant in the context of metastasising cancer cells that may not face energy stress in the blood stream but are matrix-deprived. Inhibition of AMPK might compromise the viability of these circulating cells thereby reducing the metastatic spread of cancer. Our study further suggests that varying stiffnesses experienced by cancer cells can modulate AMPK activity and this, in turn, regulates stem-like properties. Thus our study provides novel insights into various extracellular cues that regulate this kinase and contribute to cell survival and metastasis. This knowledge can be utilised in the stage-specific use of AMPK inhibitors in the treatment of breast cancer patients.
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