Global ETD Search

321	Lack of Point Mutations in Exons 11–23 of the Retinoblastoma Susceptibility Gene RB-1 in Liver Metastases of Colorectal Carcinoma Hildebrandt, Bert, Heide, I., Thiede, Christian, Nagel, S., Dieing, Annette, Jonas, S., Neuhaus, Peter, Rochlitz, Christoph, Riess, Hanno, Neubauer, Andreas January 2000 (has links) Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich. info:eu-repo/classification/ddc/610 ddc:610
322	Rôle du ribosome dans la sénescence Del Toro Del Toro, Neylen 12 1900 (has links) La sénescence est considérée comme un mécanisme de suppression tumorale puisque les cellules potentiellement dangereuses, activent leurs protéines de sauvegarde pour arrêter leur prolifération. Les protéines de sauvegarde telles que RB et p53 sont activées suite à différents stress comme des dommages à l’ADN, le raccourcissement des télomères ou l’induction oncogénique. Les cellules sénescentes restent métaboliquement actives, subissent des modifications dans leur expression génique, et sécrètent des cytokines et des chimiokines qui ont des effets paracrines pro-oncogéniques, mais peuvent également contribuer à la stabilité de l’arrêt du cycle cellulaire dans la sénescence de façon autocrine. Une des particularités du phénotype sénescent est la dégradation sélective des protéines dépendante de l’ubiquitination et du protéasome. Parmi les cibles de dégradation se trouvent des protéines impliquées dans la biogenèse du ribosome, ainsi que celles d’autres voies cellulaires requises pour la croissance de cellules cancéreuses. Ceci est lié à un stress nucléolaire qui affecte la biogenèse du ribosome, menant à l’accumulation, dans le nucléoplasme ou le nucléole, de protéines ribosomiques. Ce comportement suggère que les ribosomes des cellules sénescentes seraient structurellement différents. Par conséquent, ceci pourrait entrainer des effets sur leurs capacités à réguler l’initiation, l’élongation et/ou la terminaison de la traduction des ARN messagers (ARNm). Par ailleurs, la déplétion de certaines protéines impliquées dans la ribogenèse, ainsi que la surexpression de protéines ribosomiques telles que RPS14/uS11 amènent à la sénescence. Malgré le stress nucléolaire et les défauts de ribogenèse associés à la sénescence, les cellules sénescentes présentent des niveaux de translecture du codon d’arrêt très diminué, suggérant l’existence de défauts de production de protéines allongées en C-terminal. Nous émettons l’hypothèse que les défauts de la ribogenèse affecteraient la fonction des protéines ribosomiques et des ribosomes. Cette perturbation aurait un impact sur le rôle de suppresseur tumoral de la sénescence. Le premier objectif de cette thèse consiste à démontrer le rôle de RPL22/eL22 en tant que régulateur du cycle cellulaire et inducteur de la sénescence. Le deuxième but est de démontrer que, malgré la perturbation nucléolaire, les ribosomes des fibroblastes sénescents reconnaissent les codons d’arrêt de façon plus efficace que les ribosomes des cellules transformées, ou des cellules normales en prolifération. Nous avons démontré que le phénotype de sénescence peut être induit quand l’expression de RPL22/eL22 est augmentée. RPL22/eL22 s’accumule principalement dans le nucléole, de manière différente de RPS14/uS11, dont l’accumulation est nucléoplasmique. En effectuant des essais kinases in vitro, nous avons montré que RPL22/eL22, tout comme RPS14/uS11, peuvent interagir et inhiber le complexe CDK4-Cycline D1 afin d’activer la voie de RB et établir l’arrêt du cycle cellulaire et la sénescence. Afin de démontrer la fidélité de la terminaison de la traduction dans les cellules sénescentes, nous avons utilisé un système de rapporteurs de luciférases, pour détecter les erreurs de translecture ainsi que pour avoir un contrôle interne du système. L’inactivation de la voie du suppresseur tumoral RB par surexpression de CDK4 ou de l’oncoprotéine virale E7, nous a permis d’observer l’augmentation de la translecture dans les cellules sénescentes. Tandis que l’activation de la voie de suppression tumorale RB, à l’aide du suppresseur de tumeur PML, de la surexpression de RPL22/eL22 et de RPS14/uS11, ainsi que de l’utilisation de Palbociclib (PD-0332991), un inhibiteur des kinases CDK4/6, a montré une réduction des erreurs de translecture. Ces résultats indiquent une nouvelle fonction des protéines du ribosome en tant que suppresseurs de tumeur, permettant d’inhiber les erreurs de translecture du codon d’arrêt de façon dépendante de la voie de RB. Ces travaux suggèrent que de petites molécules ou peptides pourraient simuler les fonctions inhibitrices de ces protéines ribosomiques afin de traiter certains cancers où la voie de RB est activable. / Senescence is considered a mechanism for tumor suppression since potentially dangerous cells activate their protective proteins to stop their proliferation. Safeguard proteins such as RB and p53 are activated as a result of stress such as DNA damage, telomere shortening or oncogenic induction. Senescent cells are metabolically active, they undergo changes in their gene expression and secrete cytokines and chemokines with pro-oncogenic paracrine effects, but which can also contribute to the stability of the senescent cell cycle arrest in an autocrine way. One of the peculiarities of the senescent phenotype is the selective ubiquitination and proteasome dependent-degradation of proteins involved in ribosome biogenesis and other cellular pathways required for cancer cell growth, leading to the accumulation, in the nucleoplasm or nucleolus, of ribosomal proteins. This behavior suggests that the ribosomes of senescent cells are structurally different. Therefore, this could have effects on their ability to regulate the initiation, elongation and/or translation termination of messenger RNAs (mRNAs). Moreover, the depletion of some proteins involved in ribogenesis, as well as the overexpression of ribosomal proteins such as RPS14/uS11 lead to senescence. Despite nucleolar stress and ribogenesis defects associated to senescence, global translation does not seem to be affected in senescence. Strikingly, senescent cells have reduced translational readthrough suggesting that they have defects in the production of C-terminal extended proteins. We hypothesize that defects in ribogenesis would affect the function of ribosomal proteins and ribosomes influencing the tumor suppressor role of senescence. The first aim of this thesis is to demonstrate the role of RPL22/eL22 as a regulator of the cell cycle and senescence inducer. The second aim of this thesis is to demonstrate that, despite the nucleolar disruption, the ribosomes of senescent fibroblasts recognize stop codons more efficiently than ribosomes from transformed cells, but also than ribosomes from proliferating normal cells. We found that the senescent phenotype can be induced by enhancing the expression of RPL22/eL22. RPL22/eL22 accumulates mainly in the nucleolus, unlike RPS14/uS11, whose accumulation is nucleoplasmic. By performing an in vitro kinase assay, we showed that RPL22/eL22, just like RPS14/uS11, can interact and inhibit the CDK4-Cyclin D1 complex in order to activate the RB pathway and establish cellular arrest and senescence. To assess translation termination accuracy in senescent cells, we used a system of luciferase reporters to measure the fidelity of translation termination. Inactivation of the RB tumor suppressor pathway using CDK4 or the viral oncoprotein E7 also increased readthrough in senescent cells while overexpression of PML, a tumor suppressor that activates the RB pathway, overexpression of RPL22/eL22 and RPS14/uS11, as well as the use of Palbociclib (PD-0332991), a CDK4/6 inhibitor, reduce readthrough errors. These results indicate a novel function of ribosomal proteins as tumor suppressors, making it possible to inhibit translational readthrough errors, in a RB-dependent pathway. This work suggests that small molecules or peptides could mimic the inhibitory functions of these ribosomal proteins in order to treat cancers where the RB pathway is activatable. Sénescence Biogenèse du ribosome RPL22/eL22 CDK4-Cycline D1 Translecture Terminaison de la traduction Suppresseur tumoral rétinoblastome (RB) Rapporteur à deux luciférases Senescence Ribosome biogenesis CDK4-Cyclin D1 Readthrough Translation termination Retinblastoma tumor suppressor (RB) Dual-luciferase reporter
323	Interaktom N-terminální domény IL-1α / Interactome of IL-1α N-terminal domain Dolečková, Denisa January 2011 (has links) Interactome of IL-1α N-terminal domain Cytokines are highly effective mediators produced by various cell types within and outside of the immune system with the aim to influence the orientation, intensity, and duration of the immune response and inflammatory process. Their biological effects mediated through binding the high-affinity membrane receptors and triggering the signal transduction pathway are usually well defined. However, as it is more and more frequently observed, in addition to the exocrine function, some cytokines may show intracrine effects. For this type of cytokines, the term "dual function cytokines" has been adopted. One of these cytokines is Interleukin-1α, in which the recent research has concentrated on determining its intracellular functions. The intracellular function of interleukin-1α has not been clearly defined so far. However, apart from the absence of the conventional hydrophobic sequence, its existence is supported by the fact that the N-terminal peptide included in its precursor is highly conserved and contains nuclear localization signal. The aim of this work is to define the conditions of localization of the interleukin-1α N- terminal domain in different cellular compartments and to study proteins potentially interacting with it using fluorescent microscopy. Key words:...
324	Large tumor suppressor 1 (LATS1) and stress stimuli regulate mixed lineage kinases (MLKs) in ovarian cells. Kasturirangan, Srimathi January 2021 (has links) No description available. Biology Mitogen-activated protein kinases Mixed Lineage Kinase 3 Large Tumor Suppressor 1 14-3-3 Mixed Lineage Kinase 4 ovarian cancer invasion stress signaling
325	Intestine Homeostasis and the Role of Tumor Suppressor Gene 101 in Drosophila Melanogaster: A Dissertation Chatterjee, Madhurima 21 December 2011 (has links) Tissue homeostasis in the adult Drosophila melanogaster intestine is maintained by controlling the proper balance of stem cell self-renewal and differentiation. In the adult fly midgut, intestinal stem cells (ISCs) are the only dividing cells and their identity maintenance is crucial to the proper functioning of the fly gut. Various pathways such as Notch, JAK-STAT and Wingless are known to regulate ISC division and differentiation. Here I used a pathogen feeding model to study conditions that accelerate ISC division and guide intestinal cell differentiation favoring enterocyte development. I also examined the role of Tumor Suppressor Gene 101 (TSG101) in ISC maintenance and function. TSG101, a part of the ESCRT1 complex. It is known to stimulate the Notch pathway and to play a role in endocytic trafficking. TSG101 loss-of-function mutants show developmental defects in various fly and mammalian tissues. The protein also plays a role in virus abscission from host cells. In my experiments I have observed that TSG101 is required for ISC maintenance. TSG101 knockdown and loss of function mutant clones have defects in ISC proliferation that hinder the normal intestinal responses to oral pathogen ingestion. Based on these results I conclude that TSG101 is needed in the adult fly intestine for proper ISC maintenance and function, thereby being an important player in intestinal homeostasis. Genes Tumor Suppressor DNA-Binding Proteins Transcription Factors Homeostasis Intestines Drosophila melanogaster Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cell and Developmental Biology Digestive System Genetic Phenomena Neoplasms Physiology
326	Mdm2-p53 Signaling in Tissue Homeostasis and the DNA Damage Response: A Dissertation Gannon, Hugh S. 28 June 2012 (has links) The p53 transcription factor responds to various cellular stressors by regulating the expression of numerous target genes involved in cellular processes such as cell cycle arrest, apoptosis, and senescence. As these downstream pathways are harmful to the growth and development of normal cells when prolonged or deregulated, p53 activity needs to be under tight regulatory control. The Mdm2 oncoprotein is the chief negative regulator of p53, and many mouse models have demonstrated that absence of Mdm2 expression leads to constitutive p53 activation in a variety of cell types. While unregulated p53 can be deleterious to cells, functional p53 is essential for tumor suppression, as many human cancers harbor p53 mutations and p53 knockout mice rapidly develop spontaneous tumors. Therefore, the mechanisms that control p53 regulation by Mdm2 are critical to ensure p53 activity in the appropriate cellular context. Many genetically engineered mouse models have been created to analyze p53 and Mdm2 functions and these studies have yielded valuable insights into their physiological roles. This dissertation will describe the generation and characterization of novel mutant Mdm2 mouse models and their use to interrogate the roles of p53-Mdm2 signaling in tissue homeostasis and cell stress responses. Deletion of Mdm2 in epidermal progenitor cells of the skin and hair follicles resulted in progressive hair loss and decreased skin integrity, phenotypes that are characteristic of premature aging. Furthermore, p53 protein levels, p53 target gene expression, and cellular senescence were all upregulated in the skins of these mice, and epidermal stem cell numbers and function were diminished. These results indicate that Mdm2 is necessary to limit p53 activity in adult tissues to ensure normal stem cell function. Additional mouse models used to determine the role of Mdm2 phosphorylation will also be presented. DNA damage triggers an extensive cellular response, including activation of the ATM kinase. ATM activity is necessary for p53 protein stabilization and, therefore, p53 activation, but in vivo evidence suggests that phosphorylation of p53 itself had little effect on p53 stability. ATM was previously shown to phosphorylate MDM2 at serine residue 395 (394 in mice), and we generated knock-in mutant mouse models to study the role of this posttranslational modification in vivo. Absence of this phosphorylation site led to greatly diminished p53 stability and function in response to γ-irradiation and increased spontaneous tumorigenesis in mice. Conversely, a phosphomimic model demonstrated prolonged p53 activation in cells treated with γ-irradiation, which revealed that phosphorylation of this Mdm2 residue controls the duration of the DNA damage response. Therefore, these mouse models have uncovered new roles for the p53-Mdm2 regulatory axis in vivo and will be useful reagents in future studies of posttranslational modifications in oncogene and DNA damage-induced tumorigenesis. Proto-Oncogene Proteins c-mdm2 Tumor Suppressor Protein p53 Homeostasis DNA Damage Cell Transformation Neoplastic Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cancer Biology Cell and Developmental Biology Cells Genetic Phenomena Neoplasms Tissues
327	Identification and Characteristics of Factors Regulating Hepatocellular Carcinoma Progression and Metastasis: A Dissertation Ahronian, Leanne G. 28 March 2014 (has links) Hepatocellular carcinoma (HCC) is a common malignancy of the liver that is one of the most frequent causes of cancer-related death in the world. Surgical resection and liver transplantation are the only curative options for HCC, and tumor invasion and metastasis render many patients ineligible for these treatments. Identification of the mechanisms that contribute to invasive and metastatic disease may enlighten therapeutic strategies for those not eligible for surgical treatments. In this dissertation, I describe two sets of experiments to elucidate mechanisms underlying HCC dissemination, involving the activities of Krüppel-like factor 6 and a particular p53 point mutation, R172H. Gene expression profiling of migratory HCC subpopulations demonstrated reduced expression of Krüppel-like factor 6 (KLF6) in invasive HCC cells. Knockdown of KLF6 in HCC cells increased cell transformation and migration. Single-copy deletion of Klf6 in a HCC mouse model results in increased tumor formation, increased metastasis to the lungs, and decreased survival, indicating that KLF6 suppresses both tumor formation and metastasis in HCC. To elucidate the mechanism of KLF6-mediated tumor and metastasis suppression, we performed gene expression profiling and ChIP-sequencing to identify direct transcriptional targets of KLF6 in HCC cells. This analysis revealed novel transcriptional targets of KLF6 in HCC including CDC42EP3 and VAV3, both of which are positive regulators of Rho family GTPases. Concordantly, KLF6 knockdown cells demonstrate increased activity of the Rho family GTPases RAC1 and CDC42, and RAC1 is required for migration induced following KLF6 knockdown. Moreover, VAV3 and CDC42EP3 are also required for enhanced cell migration in HCC cells with KLF6 knockdown. Together, this work describes a novel signaling axis through which KLF6-mediated repression of VAV3 and CDC42EP3 inhibits RAC1Gmediated HCC cell migration in culture, and potentially HCC metastasis in vivo. TP53 gene mutations are commonly found in HCC and are associated with poor prognosis. Prior studies have suggested that p53 mutants can display gain-of- function properties in other tumor types. Therefore, I sought to determine if a particular hotspot p53 mutation, p53R172H, provided enhanced, gain-of-function properties compared to p53 loss in HCC. In vitro, soft agar colony formation and cell migration is reduced upon knockdown of p53R172H, indicating that this mutation is required for transformation-associated phenotypes in these cells. However, p53R172H-expressing mice did not have enhanced tumor formation or metastasis compared to p53-null mice. These data suggest that p53R172H and p53 deletion are functionally equivalent in vivo, and that p53R172H is not a gain-of-function mutant in HCC. Inhibition of the related transcription factors p63 and p73 has been suggested as a potential mechanism by which mutant p53 exerts its gain-of-function effects. Analysis of p63 and p73 target genes demonstrated that they are similarly suppressed in p53-null and p53R172H-expressing HCC cell lines, suggesting a potential explanation for the phenotypes I observed in vivo and in vitro. Together, the studies described in this dissertation increase our understanding of the mechanisms underlying HCC progression and metastasis. Specifically, we find and characterize KLF6 as a novel suppressor of HCC metastasis, and determine the contribution of a common p53 point mutation in HCC. This work contributes to ongoing efforts to improve treatment options for HCC patients. Hepatocellular Carcinoma Gene Expression Profiling p53 Genes Kruppel-Like Transcription Factors Liver Neoplasms Point Mutation rho GTP-Binding Proteins Transcription Factors Tumor Suppressor Protein p53 Dissertations, UMMS Carcinoma, Hepatocellular Genes, p53 Cancer Biology Digestive System Diseases Molecular Genetics Neoplasms
328	Autophagy-Independent Role for Beclin 1 in the Regulation of Growth Factor Receptor Signaling: A Dissertation Rohatgi, Rasika 15 January 2015 (has links) Beclin 1 is a haplo-insufficient tumor suppressor that is decreased in many human tumors. The function of Beclin 1 in cancer has been attributed primarily to its role in the degradative process of autophagy. However, the role of autophagy itself in tumorigenesis is context-dependent and can be both preventive and promoting. Due to its dual function in cancer a better understanding of this process is necessary to develop potential novel cancer therapies. To gain insight into the role of autophagy in breast carcinoma, I analyzed the autophagydependency of different subtypes of breast cancer. My results implicate that triple-negative breast carcinoma cells are more dependent on autophagy than luminal breast carcinoma cells. Chemical inhibition of autophagy decreased the tumorigenicity of triple-negative breast carcinoma cells with regard to proliferation and anchorage-independent growth. However, RNAi-mediated suppression of two autophagy genes, ATG5 and Beclin 1, revealed different outcomes. While suppression of ATG5 decreased glycolysis, Beclin 1 depletion did not affect the glycolytic rates. These results suggest autophagy-independent pro-tumorigenic effects of loss of Beclin 1 in cancer. Beclin 1 is a core component of the Vps34/Class III PI3K (PI3KC3) and Vps15/p150 complex that regulates multiple membrane trafficking events. I describe a novel mechanism of action for Beclin 1 in breast cancer involving its control of growth factor receptor signaling. I identify a specific stage of early endosome maturation that is regulated by Beclin 1, the transition of APPL1- containing phosphatidyIinositol 3-phosphate-negative (PI3P-) endosomes to PI3P+ endosomes. Beclin 1 regulates PI3P production in response to growth factor stimulation to control the residency time of growth factor receptors in the PI3P-/APPL+ signaling competent compartment. As a result, suppression of BECN1 sustains growth factor stimulated AKT and ERK activation resulting in increased breast carcinoma cell invasion. In human breast tumors, Beclin 1 expression is inversely correlated with AKT and ERK phosphorylation. Taken together my data identify a novel role for Beclin 1 in regulating growth factor signaling and reveal a mechanism by which loss of Beclin 1 expression would enhance breast cancer progression independent of its impact on autophagy. Signal Transducing Adaptor Proteins Apoptosis Regulatory Proteins Tumor Suppressor Proteins Autophagy Breast Neoplasms Neoplastic Cell Transformation Dissertations, UMMS Adaptor Proteins, Signal Transducing Cell Transformation, Neoplastic Cancer Biology Cell Biology Neoplasms
329	Validation-based insertional mutagenesis (VBIM) technology identifies adenomatous polypossis coli (APC) like protein (ALP) as a novel negative regulator of NF-κB Mundade, Rasika S. 01 1900 (has links) Colorectal cancer (CRC) is the third leading cause of cancer related deaths in the United States. The nuclear factor κB (NF-κB) is an important family of transcription factors whose aberrant activation has been found in many types of cancer, including CRC. Therefore, understanding the regulation of NF-κB is of ultimate importance for cancer therapy. Using a novel validation-based insertional mutagenesis (VBIM) strategy, our lab has identified the novel adenomatous polyposis coli (APC) like protein (ALP) gene as a negative regulator of NF-κB. Preliminary studies from our lab demonstrated that overexpression of ALP led to decreased NF-κB activity by κB reporter assay and electrophoresis mobility gel shift assay (EMSA). The current project aims to further evaluate the role of ALP in the regulation of NF-κB signaling in CRC cells. We found that overexpression of ALP in human CRC HT29 cells greatly reduced both the number and the size of colonies that were formed in a soft agar assay. ALP overexpression also decreased the cell growth rate and cell migration ability, while shRNA mediated knockdown of ALP showed opposite effects, confirming that ALP is a tumor suppressor in CRC HT29 cells. Overexpression of ALP led to decreased NF-κB activity by κB reporter assay and condition media assay in CRC HT29 cells. Furthermore, immunohistochemical analysis with human colon vii tissues revealed that there is a gradual loss of ALP protein with tumor progression. We also found that ALP predominantly localizes in the cytoplasm, and binds to the p65 subunit of NF-κB, and might be functioning downstream of IκB kinase (IKK). In summary, in this study, we provide evidence regarding the tumor suppressor role of ALP in CRC by functioning as novel negative regulator of NF-κB. This discovery could lead to the establishment of ALP as a potential biomarker and therapeutic target in CRC. VBIM ALP NF-kB Colon Cancer Colon (Anatomy) -- Cancer Rectum -- Cancer NF-kappa B (DNA-binding protein) Mutagenesis -- Genetics Cancer -- Genetic aspects Transcription factors Genetic transcription Antioncogenes Tumor suppressor proteins
330	Phospho-regulation and metastatic potential of Murine Double Minute 2 Batuello, Christopher N. 21 December 2012 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Murine double minute (Mdm2) is a highly modified and multi-faceted protein that is overexpressed in numerous human malignancies. It engages in many cellular activities and is essential for development since deletion of mdm2 is lethal in early stages of embryonic development. The most studied function of Mdm2 is as a negative regulator of the tumor suppressor protein p53. Mdm2 achieves this regulation by binding to p53 and inhibiting p53 transcriptional activity. Mdm2 also functions as an E3 ubiquitin ligase that signals p53 for destruction by the proteasome. Interestingly recent evidence has shown that Mdm2 can also function as an E3 neddylating enzyme that can conjugate the ubiquitin-like molecule, nedd8, to p53. This modification results in inhibition of p53 activity, while maintaining p53 protein levels. While the signaling events that regulate Mdm2 E3 ubiquitin ligase activity have been extensively studied, what activates the neddylating activity of Mdm2 has remained elusive. My investigations have centered on understanding whether tyrosine kinase signaling could activate the neddylating activity of Mdm2. I have shown that c-Src, a non-receptor protein tyrosine kinase that is involved in a variety of cellular processes, phosphorylates Mdm2 on tyrosines 281 and 302. This phosphorylation event increases the half-life and neddylating activity of Mdm2 resulting in a neddylation dependent reduction of p53 transcriptional activity. Mdm2 also has many p53-independent cellular functions that are beginning to be linked to its role as an oncogene. There is an emerging role for Mdm2 in tumor metastasis. Metastasis is a process involving tumor cells migrating from a primary site to a distal site and is a major cause of morbidity and mortality in cancer patients. To date, the involvement of Mdm2 in breast cancer metastasis has only been correlative, with no in vivo model to definitively define a role for Mdm2. Here I have shown in vivo that Mdm2 enhances breast to lung metastasis through the up regulation of multiple angiogenic factors, including HIF-1 alpha and VEGF. Taken together my data provide novel insights into important p53-dependent and independent functions of Mdm2 that represent potential new avenues for therapeutic intervention. Mdm2 Nedd8 Metastasis Phosphorylation c-Src Cellular signal transduction Protein-tyrosine kinase -- Inhibitors p53 antioncogene -- Analysis Phosphorylation Metastasis Antioncogenes Tumor suppressor proteins Genetic transcription Ubiquitin Proteomics Post-translational modification Ligases

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