Assay of epigenetics changes in SFRP2 gene in grade II and grade III gliomas able to infleunce drug effects / Vaistų poveikį galinčių įtakoti SFRP2 geno epigenetinių pakitimų tyrimai antrojo ir trečiojo laipsnio gliomose

Kaselytė, Agnė

21 June 2010

Two different mechanisms participate in the loss of SFRPs expression in cancer cells: allelic loss and epigenetic silencing [1]. Methylation status in grade II and grade III glioma differs. From previous studies which were performed in Germany, 2010 by S. Gotze, M. Wolter, G. Reifenberger, O. Muller and S. Sievers [2], it is known that in grade II glioma SFRP2 gene supposed to be methylated (12.5% - 2 samples from 16 were methylated) , while in grade III glioma commonly is unmethylated (0% - from 14 samples no samples were methylated). SFRP2 gene mRNA expression decreases during transformation of grade II to grade III glioma, what’s why our researches were based on idea that SFRP2 expression level decreases because of methylation on this gene. Secondly, another hypothesis we supported that SFRP2 gene could be silenced due to loss of heterozygosity (LOH). IDH1 (isocitrate dehydrogenase1) mutation occurs in tumor tissues while is absent in normal tissue. Third hypothesis which we done, that IDH1 mutation is a common event in malignant glioma tissues, and can be used for glioma diagnostic as biomarker. Our object for this master thesis was to find SFRP2 (Secreted frizzled related protein-2) gene promoter methylation level in grade II and grade III gliomas. To compare the results with the results publicated in previous studies. The main goal of this thesis is to perform methylation study of the promoter region of SFRP2 gene on 86 samples (42 WHO... [to full text] / Centrinės nervų sistemos (CNS) gliomos yra navikai, kilę iš paraminio nervinio audinio, esančio smegenyse. Yra keletas skirtingų rūšių paraminio nervinio audinio ląstelių: astrocitų, oligodendrocitų ir ependimocitų. Pirminiai centrinės nervų sistemos navikai sudaro apie 2 % visų vėžių atveju. Tuo tarpu gliomos sudaro 64-72% visų pirminių smegenų vėžių. Pirminiai CNS navikai yra lyderiaujanti priežastis, sukelianti vaikų mirtis ir ketvirtoje vietoje pagal svarbą įtakojanti suaugusiųjų (virš 54 metų) mirtis. Kasmet Jungtinėse Amerikos valstijose yra registruojama apie 14 000 naujų gliomų atveju, t.y. 5 nauji atvejai/ 100 000 gyventojų. Prancūzijoje šis skaičius yra 3000 naujų gliomų per metus, t.y. 8 nauji atvejai 100 000 gyventojų. Pagal statistinius duomenis, Lietuvoje 2001 metais buvo užregistruota 247 nauji pacientai sergantys gliomomis ( 7.1 nauji atvejai / 100 000 gyventojų), o 2007 metais 211 naujų susirgimų gliomomis ( 6.2 / 100 000 gyventojų). Pagal Pasaulinės Sveikatos Organizacijos (PSO) priimtus kriterijus (pyktibiškumo laipsnį) gliomos yra skirstomos į keturias stadijas : I- policitinė astrocitoma ; II- astrocitoma, oligo-astrocytoma, oligodendroglioma ; III- anaplastinė astrocitoma, anaplastinė oligoastrocitoma, anaplastinė oligodendrolglioma ; IV- glioblastoma. Daugumos atliktų studijų metu nustatyta, jog gyvenimo prognozė labai priklauso nuo piktybiškumo laipsnio. I stadijos gliomos nėra pavojingos, po sėkmingo gydymo sergantieji išgyvena... [toliau žr. visą tekstą]

Pharmacy

Glioma

Methylation

SFRP2 gene

Glioma

SFRP2

Methylation

Histologische Klassifikation für degenerativ geschädigte Menisken - die Wnt-Signalwegsmoleküle RSPO2 und SFRP2 in humanem Meniskusgewebe / Histological classification for degenerative meniscus - the wnt modulating proteins RSPO2 and SFRP2 in human meniscus tissue

Roth, Moritz

10 February 2014

No description available.

610

Meniskus

Arthrose

RSPO2

SFRP2

wnt

meniscus

osteoarthritis

RSPO2

SFRP2

wnt

Orthopädie (PPN619876204)

The function of TGF-beta1 in ICUAW and the characterization of Sfrp2, a TGF-beta1 target, in skeletal muscle atrophy

Zhu, Xiaoxi

08 January 2015

Transforming growth factor beta 1 (TGF-beta1) ist ein multifunktionales Zytokin, welches eine Rolle in der Sepsis und in der Sepsis-induzierten Myopathie spielen könnte. Weiterhin könnten erhöhte TGF-beta1-Level zur Muskelschwäche, die mit der Intensivpflege assoziiert ist (engl. intensiv care unit-acquired weakness, ICUAW), beitragen. Der TGF-beta1- Signalweg wurde in Skelettmuskelbiopsien von ICUAW-Patienten heraufreguliert. Secreted frizzled related protein 2 (SFRP2) wurde in einer Gen-Set-Anreicherungsanalyse als das am höchsten regulierte Gen identifiziert. Im Mausmodell führten Sepsis und Hunger zu einer verringerten Sfrp2-Expression, während dies in der Denervation-induzierten Skelettmuskelatrophie nicht festzustellen war. In differenzierten C2C12-Myotuben führte TGF-beta1 zu einer verringerten Sfrp2-mRNA- und Proteinexpression. Luciferase-Assays deuteten auf eine TGF-beta1-abhängige Herunterregulation von Sfrp2 hin, welche auf Promoterebene durch mögliche negative regulatorische Elemente im Sfrp2-Promoter vermittelt wurde. Weiterhin wurde eine TGF-beta1 induzierte Muskelatrophie durch transkriptionelle Repression der myosin heavy chain Gene beobachtet. Im Gegensatz dazu veränderte TGF-beta1 nicht den proteasomalen Abbau muskulärer Proteine. Die Genexpression von Tripartite motif containing 63 und F-box only protein 32 war hingegen leicht herunterreguliert. TGF-beta1-induzierte Atrophie in differenzierten C2C12-Myotuben wurde teilweise durch rekombinantes Sfrp2 aufgehoben. Weiterhin wurde eine direkte physikalische Interaktion zwischen Sfrp2 und TGF-beta1 gefunden, welche diesen Effekt verursacht haben könnte. Zusammengefasst lässt sich feststellen, dass der TGF-beta1- Signalweg eine wichtige Rolle in der ICUAW durch Inhibition der myosin heavy chain Expression spielt. TGF-beta1-abhängige Herunterregulation von Sfrp2 könnte zu einer Feedback-Antwort, die das Ausmaß der Atrophie durch TGF-beta1 verstärkt, führen. / Transforming growth factor beta 1 (TGF-beta1) is a multifunctional cytokine that may play a role in sepsis and in sepsis-induced myopathy. Our group speculated that increased TGF-beta1 could contribute to intensive care (ICU)-acquired weakness (ICUAW), a catastrophic muscle disease in critically ill patients. We found that TGF-beta1 signaling in skeletal muscle biopsies of ICUAW patients was upregulated. Secreted frizzled related protein 2 (SFRP2) was the most regulated gene identified by gene set enrichment analysis (GSEA). I then studied the regulation and function of SFRP2 in different skeletal muscle atrophy models. In three mouse models, downregulated Sfrp2 expression was observed in sepsis and starvation, but not in denervation-induced skeletal muscle atrophy. In differentiated C2C12 myotubes, TGF-beta1 downregulated Sfrp2 expression on both mRNA and protein levels. Luciferase assays suggested that TGF-beta1-dependent downregulation of Sfrp2 was mediated at the promoter level through possible negative regulatory elements in the Sfrp2 promoter. I also observed that TGF-beta1-induced muscle atrophy was accompanied by transcriptional repression of myosin heavy chain genes. In contrast, TGF-beta1 did not increase proteasomal degradation of muscular proteins since gene expression of Tripartite motif containing 63 (Trim63) and F-box only protein (Fbxo32) was not upregulated; instead, they were slightly downregulated. TGF- beta1-induced differentiated C2C12 myotube atrophy was partially reversed by recombinant Sfrp2. This inhibitory effect could have resulted from direct interaction between Sfrp2 and TGF-beta1, since I found a physical interaction between these two proteins. Taken together, TGF-beta1 signaling pathway could play an important role in ICUAW via inhibition of myosin heavy chain expression. TGF-beta1-dependent downregulation of Sfrp2 may establish a feedback loop augmenting the atrophic effect of TGF-beta1.

Skelettmuskelatrophie

Skeletal muscle atrophy

570 Biowissenschaften, Biologie

32 Biologie

XG 7900

ddc:570

Relations fonctionnelles entre les voies des hormones thyroïdiennes et WNT dans la physiopathologie intestinale : étude de la fonction de sFRP2 / Functional relations between the thyroïd hormones and WNT pathways in the intestinal physiopathology : study of sFRP2 function

Skah, Seham

27 September 2012

L'épithélium intestinal est un tissu en constant renouvellement, grâce à des cellules souches somatiques présentes dans les cryptes intestinales. Le renouvellement perpétuel et l’homéostasie de ce tissu sont assurés par plusieurs réseaux de signalisation. Il est maintenant admis que la dérégulation de ces mêmes voies est impliquée dans le processus d’initiation et/ou de progression tumorale. Mon laboratoire a décrit l'implication des hormones thyroïdiennes (HT) et de leur récepteur nucléaire TRα1 dans le contrôle de l'homéostasie intestinale, via la régulation de la voie Wnt, jouant un rôle clé dans la physiopathologie de ce tissu. Plus précisément, TRα1 active l’expression et la stabilisation de β-caténine via un mécanisme impliquant le facteur sFRP2. Au cours de ma thèse, j’ai participé, d’une part à l’étude de souris transgéniques surexprimant TRα1 dans l’épithélium intestinal et à l’analyse des mécanismes moléculaires de la régulation croisée entre TRα1 et la voie Wnt canonique dans l’induction des tumeurs intestinales. Nous avons donc démontré un rôle oncogénique de TRα1 dans l’épithélium intestinal. De plus, le mécanisme moléculaire et fonctionnel implique les deux effecteurs de la voie canonique, β-caténine et TCF4. D’autre part, j’ai analysé la fonction de sFRP2 dans la physiopathologie intestinale, et son action sur la voie Wnt. D’une manière intéressante, l’étude de la fonction de sFRP2 nous a permis de révéler son rôle original dans la différenciation des cytotypes épithéliaux. De plus, nous avons montré que sFRP2 est un modulateur positif des voies Wnt canonique et non canonique (JNK). Par ailleurs, l’absence d’expression de sFRP2 a pour conséquence d’augmenter l’apoptose dans les cryptes intestinales et ainsi diminuer le nombre de tumeurs chez des animaux double mutants sFRP2-/-/Apc+/1638N comparé aux simple mutants Apc+/1638N. Ces résultats fournissent des éléments originaux et importants sur les relations fonctionnelles entre les voies des HT et Wnt. / The intestinal epithelium is a tissue constantly renewing through somatic stem cells located within the crypts. Several signalling pathways control this process and the homeostasis in this tissue. It is now recognized that the deregulation of these pathways is involved in the process of initiation and/or progression of intestinal tumors. My laboratory has described the involvement of thyroid hormones (TH) and their nuclear receptor TRα1 in the control of the intestinal homeostasis via the regulation of Wnt pathway, which plays a key role in the intestinal physiopathology. Specifically, TRα1 directly activates the expression of β-catenin and controls its stabilization through a mechanism involving sFRP2 (secreted frizzled-related protein 2). During my thesis, I participated to the characterization of transgenic mice overexpressing TRα1 in the intestinal epithelium. Moreover, I have been involved in the study of the molecular mechanisms of the cross-regulation between TRα1 and the canonical Wnt in the induction of intestinal tumors. We have therefore demonstrated an oncogenic role of TRα1 in the intestinal epithelium. In addition, the molecular and functional mechanisms involve both effectors of the canonical pathway, β-catenin and TCF4. On the other hand, I carried out the study of sFRP2 function in the intestinal physiopathology, and its action on the Wnt pathway. My data strongly suggest that sFRP2 plays an essential role in the differentiation of epithelial cytotypes. In addition, we showed that sFRP2 is a positive modulator of the canonical and non-canonical (JNK) Wnt. For instance, the absence of sFRP2 expression increases the apoptosis in the intestinal crypts and thus reduces the number of tumors in the double mutant sFRP2-/-/Apc+/1638N compared to simple mutant Apc+/1638N. These results provided original and important data of the functional relationships between TH and Wnt pathways.

Physiopathologie intestinale

Hormones thyroïdiennes (HT)

Récepteur nucléaire TRα1

Voie Wnt canonique (Wnt/β-caténine)

Voie Wnt non canonique (JNK)

Intestinal physiopathology

Thyroid Hormones (TH)

Thyroid Receptor TRα1

Canonical Wnt pathway (Wnt/β-catenin)

Non-canonical Wnt pathway (JNK)