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AHNAK regula a formação e troca de vesículas extracelulares entre células tumorais de mama e fibroblastos. / AHNAK regulates the formation and exchange of extracellular vesicles from breast tumor cells and fibroblasts.Silva, Thaiomara Alves 01 September 2015 (has links)
O sucesso no desenvolvimento de tumores não dependente somente de mutações, mas também é influenciado pelo microambiente do tumor; nele ocorre a interação entre as células tumorais e o estroma. Essa interação pode ser mediada por vesículas liberadas por essas células para o meio extracelular. Essas vesículas atuam na comunicação celular que pode influenciar a progressão tumoral. O objetivo deste estudo foi analisar as interações mediadas por vesículas entre células tumorais e fibroblastos normais. As células tumorais foram plaqueadas sobre a monocamada de fibroblastos e carregadas com diferentes corantes vitais. Nossos resultados evidenciaram a presença e a troca de vesículas entre as células em co-cultura. Vesículas isoladas mostraram tamanhos heterogêneos. Células tumorais possuem mais vesículas que as células normais. As vesículas são compostas pelas proteínas AHNAK e Anexinas. AHNAK foi detectada em vesículas trocadas e estava aumentada em tumores. AHNAK é molécula estrutural das vesículas extracelulares que pode influenciar a biologia dos tumores de mama. / The successful development of tumors is not only dependent on cell mutations, but also driven by the tissue microenvironment; relies on interaction of cells and their surrounding stroma. Some cell types release vesicular structures into the extracellular space that would be involved in cellular communication and tumor progression. The aim of this study was to analyze vesicle-mediated interactions between tumor cells and normal fibroblasts. Tumor cells were plated above fibroblasts monolayer and both loaded with different vital dyes. Our results evidenciated presence and exchange of vesicles between breast tumor cells and fibroblasts in co-culture. Vesicles isolated showed heterogeneous sizes. Tumor cell showed more vesicles than normal cells. These vesicles were composed of AHNAK and Annexins proteins. The protein AHNAK was detected in exchanged vesicles and was increased in tumors when compared to normal breast tissues. AHNAK could represent a vesicle structural molecule that would influence breast tumor biology.
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AHNAK regula a formação e troca de vesículas extracelulares entre células tumorais de mama e fibroblastos. / AHNAK regulates the formation and exchange of extracellular vesicles from breast tumor cells and fibroblasts.Thaiomara Alves Silva 01 September 2015 (has links)
O sucesso no desenvolvimento de tumores não dependente somente de mutações, mas também é influenciado pelo microambiente do tumor; nele ocorre a interação entre as células tumorais e o estroma. Essa interação pode ser mediada por vesículas liberadas por essas células para o meio extracelular. Essas vesículas atuam na comunicação celular que pode influenciar a progressão tumoral. O objetivo deste estudo foi analisar as interações mediadas por vesículas entre células tumorais e fibroblastos normais. As células tumorais foram plaqueadas sobre a monocamada de fibroblastos e carregadas com diferentes corantes vitais. Nossos resultados evidenciaram a presença e a troca de vesículas entre as células em co-cultura. Vesículas isoladas mostraram tamanhos heterogêneos. Células tumorais possuem mais vesículas que as células normais. As vesículas são compostas pelas proteínas AHNAK e Anexinas. AHNAK foi detectada em vesículas trocadas e estava aumentada em tumores. AHNAK é molécula estrutural das vesículas extracelulares que pode influenciar a biologia dos tumores de mama. / The successful development of tumors is not only dependent on cell mutations, but also driven by the tissue microenvironment; relies on interaction of cells and their surrounding stroma. Some cell types release vesicular structures into the extracellular space that would be involved in cellular communication and tumor progression. The aim of this study was to analyze vesicle-mediated interactions between tumor cells and normal fibroblasts. Tumor cells were plated above fibroblasts monolayer and both loaded with different vital dyes. Our results evidenciated presence and exchange of vesicles between breast tumor cells and fibroblasts in co-culture. Vesicles isolated showed heterogeneous sizes. Tumor cell showed more vesicles than normal cells. These vesicles were composed of AHNAK and Annexins proteins. The protein AHNAK was detected in exchanged vesicles and was increased in tumors when compared to normal breast tissues. AHNAK could represent a vesicle structural molecule that would influence breast tumor biology.
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The role of BET proteins in castration-resistant prostate cancer disseminationShafran, Jordan Seth 01 June 2020 (has links)
The inevitable progression of advanced prostate cancer to castration resistance, and ultimately to lethal metastatic disease, depends on primary or acquired resistance to conventional androgen-deprivation therapy (ADT) and accumulated resistance mechanisms to evade androgen receptor (AR) suppression. Whereas the canonical androgen/AR signaling axis maintains prostate cell growth, differentiation and survival, in prostate cancer cells, AR adaptations that arise in response to ADT are not singular, but diverse, and include gene amplification, mutation and even complete loss of receptor expression. Collectively, each of these AR adaptations contributes to a complex, heterogenous, ADT-resistant tumor that culminates in prostate tumor cells transitioning from epithelial to mesenchymal states (EMT) and the development of metastatic castration-resistant prostate cancer (mCRPC). Here, we examined prostate cancer cell lines that model common CRPC subtypes, each with different AR composition, and focused on novel regulators of tumor progression, the Bromodomain and ExtraTerminal (BET – BRD2, BRD3 and BRD4) family of proteins, to test the hypothesis that each BET family member regulates EMT and underlying characteristics such as cell motility and invasiveness. We systematically manipulated the BET proteins and found that BRD4
regulates cell migration and invasion across all models of CRPC, regardless of aggressiveness and AR status, whereas BRD2 and BRD3 only regulate cell migration and invasion in less aggressive models that retain AR expression or signaling. We determined that BRD4’s contribution to this process occurs through the transcriptional regulation of AHNAK, SNAI1 and SNAI2, which are EMT genes linked to promotion of metastasis in a diverse set of cancers. Furthermore, treatment of CRPC cell lines with low doses of MZ1, a small-molecule, BRD4-selective degrader, inhibits EMT and metastatic potential. Overall, these results reveal a novel, BRD4-regulated EMT gene signature that may be targetable to treat metastatic castration-resistant prostate cancer.
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Development of a cellular mechanistic assay for the SET and MYND domain containing methyltransferase SMYD2, identification and validation of a novel substrate, and functional characterization of its inhibitionEggert, Erik 15 August 2017 (has links)
Protein Methyltransferasen sind oftmals fehlreguliert in Tumorzellen und stellen potenzielle Ziele in der Krebstherapie dar. Das SET und MYND Domain enthaltene Protein 2 (SMYD2) wurde als potenzielles Onkogen beschrieben und eine Überexpression korreliert mit einer schlechten Prognose. Für SMYD2 wurden verschiedene Substrate beschrieben u.a. Histon H3 und der Tumorsuppressor p53, allerdings ist die Biologie dieses Enzymes kaum verstanden. Durch die Entwicklung einer Testsubstanz zur spezifischen Hemmung von SMYD2 könnte ein möglicher therapeutischer Nutzen besser untersucht werden. Hierfür wurde ein zellulärer mechanistischer Test zur Messung der SMYD2 Aktivität mittels eines methylierungs-spezifischen Antikörpers etabliert. Mit Hilfe dieses Tests wurde BAY-598 als selektiver und potenter zellulärer Hemmer für SMYD2 identifiziert. Im weiteren Verlauf dieser Arbeit wurden mittels eines Proteomansatzes nach SMYD2 Überexpression hunderte neue zelluläre Lysinmethylierungen identifiziert. Hierbei wurde das AHNAK Protein als neues SMYD2-Substrat identifiziert und validiert. Die AHNAK Methylierung konnte in verschiedenen Zelllinien und im Muskelgewebe von Mäusen nachgewiesen werden. Im letzten Teil der Arbeit wurde die spezifische Testsubstanz BAY-598 genutzt, um verschiedene in der Literatur aufgekommene Hypothesen zur SMYD2 Funktion zu testen. Die vorliegende Arbeit hat dazu beigetragen die potente und selektive SMYD2 Testsubstanz BAY-598 zu entwickeln. Außerdem wurde mit AHNAK ein neues SMYD2 Substrat identifiziert und validiert. Die Relevanz des SMYD2 Enzymes und der AHNAK Methylierung erfordert weitere Forschungsarbeit, die durch die Bereitstellung der spezifischen Testsubstanz BAY-598 deutlich verbessert werden sollte. / Protein methyltransferases are often misregulated in tumor cells and display a potential target for cancer therapy. The SET and MYND domain containing protein 2 (SMYD2) was described as a potential oncogene and overexpression correlated with a worse prognosis. Several substrates for SMYD2 had been described among them histone H3 and p53. However, the biology of SMYD2 is poorly understood. By developing a small molecule inhibitor of SMYD2 its therapeutic role could be better evaluated. Therefore, a cellular mechanistic assay was developed using a methylation specific antibody. With that assay BAY-598 was identified as a potent and selective cellular inhibitor of SMYD2. In the following a proteomic approach revealed hundreds of novel cellular lysine methylation sites in SMYD2 overexpression cells. Among these AHNAK protein was validated as a novel SMYD2 substrate, which was present in several cell lines as well as in muscle of mice. Finally, BAY-598 was used to test several hypothesized functions of SMYD2 in different cell line models. Taken together, the current work strongly supported the development of the probe inhibitor BAY-598 and the discovery of AHNAK as a novel SMYD2 methylation substrate. The relevance of SMYD2 and AHNAK methylation needs further investigation, which should be supported by BAY-598.
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Funktionelle Untersuchungen von Ahnak durch Protein-Protein-Wechselwirkungen und in Ahnak-DefizienzmodellenPetzhold, Daria 14 December 2007 (has links)
Ahnak ist ein ubiquitäres Protein, das an einer Vielzahl biologischer Prozesse beteiligt ist. In der Herzmuskelzelle ist Ahnak überwiegend am Sarkolemma lokalisiert und bindet an Aktin und an die regulatorischen Beta2-Untereinheit des L-Typ-Kalzium-Kanals. Das Ziel dieser Arbeit war die Funktion von Ahnak im Herzen mit Hilfe eines Knock-out-Maus-Modells und in Bindungsstudien zu untersuchen. Morphologische Untersuchungen zeigten, dass das Längenwachstum adulter Kardiomyozyten bei Ahnakdefizienz signifikant reduziert war. Die Kontraktionseigenschaften adulter isolierter Ahnak-defizienter Kardio-myozyten (im Alter von 6 Monaten) waren ebenfalls verändert. Die Kontraktions- und Relaxaktionsgeschwindigkeiten waren erhöht. Eine Erhöhung des diastolischen Kalzium-Spiegels zeigten die Kardiomyozyten schon im Alter von 3 Monaten. Diese beobachteten phänotypischen Veränderungen lassen vermuten, dass die Aktivität des L-Typ-Kalzium-Kanals erhöht ist. In dieser Arbeit konnte das PXXP-Motiv, in der C-terminalen Ahnak-Domäne, als die hochaffine Beta2-Bindungsstelle (KD ~ 60 nM) identifiziert werden. Substitution von Prolin gegen Alanin verringerte zwar die Bindung zur Beta2-Untereinheit dramatisch (KD ~ 1 µM), hob sie aber nicht auf. In weiteren Bindungsstudien zeigte sich, dass die natürlich vorkommende Missensmutation I5236T die Bindung zur regulatorischen Beta2-Untereinheit verstärkte, dagegen verminderte die PKA-abhängige Phosphorylierung der beiden Proteinpartner die Bindung. Experimente am ganzen isoliert perfundierten Herzen zeigten, dass Ahnak-Knock-Out-Herzen geringer Beta-adrenerg stimulierbar waren. Ahnak scheint wie eine physiologische Bremse des kardialen Kalzium-Kanals zu wirken. / Ahnak is an ubiquitous protein with in unique structure, which has been implicated in cell type specific functions. In cardiomyocytes, ahnak is predominantly localized at the sarcolemma and is associated with actin and with the regulatory beta2 subunit of the L-type calcium-channel. The aim of this work was to unravel the function of ahnak in the heart, using a knock-out-mouse model and binding studies. Morphological studies showed a significant decrease in the cell-length of ahnak deficient cardiomyocytes. The contractile parameters of isolated adult ahnak deficient cardiomyocytes (in the age of 6 month) were altered. The development of tension and relaxation were increased. An increase of diastolic calcium was already observed at the age of 3 month. In general the observed phenotypic changes suggested an increased activity of the L-type calcium-channel. In this study, a PXXP-motif, which locates in ahnaks C-terminus, was identified as the high affinity beta2 subunit binding site (KD ~ 60 nM). Substitution of both proline residues by alanine reduced, but did not abolish the binding (KD ~ 1 µM). Further binding studies revealed that the natural occurring ahnak missense mutation I5236T increases the binding affinity to the regulatory beta2 subunit. By contrast PKA dependant phosphorylation of both protein partners decreases the interaction. In studies with isolated perfused working heart preparations, the ahnak deficient hearts were less beta-adrenergic stimulated than hearts from wild type. Taken together ahnak seems to be a physiological brake of the cardiac calcium-channel.
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Studies of Autoantibodies in Systemic and Organ-Specific Autoimmune DiseaseSköldberg, Filip January 2003 (has links)
Systemic lupus erythematosus (SLE) is the prototypic systemic autoimmune disease, whereas autoimmune polyendocrine syndrome type 1 (APS1) is a rare autosomal disorder characterized by combinations of organ-specific autoimmune manifestations including hypoparathyroidism and intestinal dysfunction, and may serve as a model for organ-specific autoimmunity. Autoantibodies directed against proteins expressed in the affected tissues are found in both diseases. From a chondrocyte cDNA expression library, we identified the protein AHNAK as an autoantigen in SLE. Anti-AHNAK antibodies were found in 29.5% (18/61) of patients with SLE, 4.6% (5/109) of patients with rheumatoid arthritis, and 1.2% (2/172) of blood donors. Using a candidate approach, we analyzed the prevalence in APS1 and other organ-specific autoimmune diseases, of autoantibodies against the pyridoxal phosphate-dependent enzymes histidine decarboxylase (HDC) and cysteine sulfinic acid decarboxylase (CSAD), which are structurally closely related to known autoantigens. Anti-HDC and anti-CSAD reactivity was detected exclusively in APS1 patient sera. Anti-HDC antibodies were detected in 37.1% (36/97) of the APS1 sera, did not cross-react with aromatic L-amino acid decarboxylase, and were associated with intestinal dysfunction and loss of histamine-producing gastric enterochromaffin-like cells. In contrast, anti-CSAD reactivity was detected in 3.6% (3/83) of APS1 sera and cross-reacted with recombinant glutamic acid decarboxylase. From a parathyroid cDNA expression library, novel spliced transcripts of the CLLD4 gene on human chromosome 13q14, encoding 26 and 31 kDa isoforms recognized by autoantibodies in 3.4% (3/87) of APS1 patients, were identified and found to be preferentially expressed in lung and ovary. Both isoforms contain an N-terminal BTB/POZ domain, similarly to the TNF-alpha-regulated protein B12, localize both to the cytoplasm and nucleus in transfected COS cells, and form oligomers in vitro. The CLLD4 gene is located in a region frequently deleted in several forms of cancer, including lung and ovarian tumors. In conclusion, we have identified and partially characterized AHNAK and HDC as two common targets of autoantibodies in SLE and APS1, respectively. We have also identified CSAD and CLLD4 as two minor autoantigens in APS1, one of which is a novel protein with unknown function.
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