Análise de Marcadores Gênicos de Estresse Genotóxico em Fibroblastos Humanos Normais e Células de Glioblastoma. / Analysis of Gene Markers of Genotoxic Stress in Human Normal Fibroblasts and Glioblastoma Cells.

Gustavo Nóriz Berardinelli

24 August 2011

Muitos genes têm sido indicados como responsivos ao estresse genotóxico, mas devido à necessidade de validação, a busca por marcadores gênicos continua. Vários genes são relacionados ao sistema ubiquitina-proteassomo (UPS), o qual é responsável pela remoção seletiva de proteínas, sendo que falhas no UPS têm sido relacionadas a doenças neurodegenerativas e ao câncer. Assim, o presente trabalho teve como objetivo a busca e confirmação de marcadores gênicos de resposta ao estresse genotóxico, por meio do estudo da expressão transcricional e protéica dos genes ERN1, EIF2AK3, GADD153 e TRAF2, visando à confirmação das respostas em linhagens de fibroblastos (GM07492A e AS405) e de glioblastoma (U87MG), sob tratamentos com peróxido de hidrogênio (H2O2) e Bleomicina (Blm). Foram utilizados o Ensaio Cometa, a análise de expressão gênica transcricional por qPCR em tempo real e de expressão gênica ao nível protéico (imunofluorescência). Os resultados mostraram que os tratamentos empregados foram capazes de induzir danos no DNA, sendo que a sensibilidade ao tratamento e a capacidade de recuperação das linhagens foi variável dependendo do agente testado. A análise de expressão gênica mostrou que GM07492A apresentou indução dos genes ERN1 e GADD153 após tratamento com H2O2 (resposta precoce, zero e 2 h) e Blm (durante todo pós-tratamento). A linhagem AS405 exibiu indução de ERN1 e GADD153 para H2O2, enquanto que para Blm foram induzidos os genes EIF2AK3 e GADD153. Para U87MG, a indução de EIF2AK3 pelo H2O2 ocorreu de modo tardio, enquanto GADD153 mostrou-se induzido após ambos os tratamentos. A proteína ERN1 apresentou expressão discreta e pontual, inclusive nos pontos onde não houve indução transcricional, indicando uma expressão basal. Essa proteína se expressou em GM07492A no tratamento com Blm em zero hora, diferentemente de AS405. Para U87MG tratada com H2O2 observou-se discreta expressão de ERN1, sendo mais evidente para Blm. Quanto à proteína GADD153, esta foi expressa em fibroblastos nos vários tempos analisados. No entanto, U87MG mostrou expressão nuclear apenas nas células tratadas, sendo mais evidente para H2O2 comparativamente à Blm. Assim, as alterações observadas nos perfis de expressão gênica são compatíveis com a indução de danos no DNA, indicando o envolvimento de genes do UPS nas respostas celulares ao estresse genotóxico. Em conjunto, os resultados estimulam uma avaliação mais detalhada desses genes como marcadores de resposta ao estresse e evidencia a sua importância no cenário da via UPS. / Many genes have been reported as responsive to genotoxic stress, but due to the need of validation, the search for genetic markers still continues. Several genes are related to the ubiquitin-proteasome system (UPS), which is responsible for the selective removal of proteins, and UPS failures have been associated to neurodegenerative diseases and cancer. Thus, this study aimed the search and confirmation of genetic markers that were responsive to genotoxic stress. For this, we evaluated the transcriptional or protein expression of the genes ERN1, EIF2AK3, GADD153 and TRAF2, seeking confirmation of responses in fibroblast cell lines (GM07492A and AS405) and glioblastoma (U87MG) under treatment with hydrogen peroxide (H2O2) and bleomycin (BLM). We used the Comet Assay, the transcriptional analysis of gene expression by quantitative real-time PCR and protein expression byimmunofluorescence. The results showed that the treatments employed were able to induce DNA damage, and that cell sensitivity to treatments and recovery capability of cell lines varied according to the tested agent. The gene expression analysis showed that GM07492A presented induction of ERN1 and GADD153 genes after treatment with H2O2 (early response, zero and 2 h) and Blm (throughout the post-treatment). The cell line AS405 showed induction of GADD153 and ERN1 after H2O2, whereas with Blm the genes induced were EIF2AK3 and GADD153. For U87MG, the induction of EIF2AK3 by H2O2 occurred at a later stage, while GADD153 was promptly induced after both treatments. The protein ERN1 showed discreet and punctual expression, even at time point without transcriptional induction, indicating a basal expression. This protein was expressed in GM07492A by treatment with Blm at zero hour, differently of AS405. For U87MG treated with H2O2, ERN1 showed a slight expression, being more evident for Blm. Regarding GADD153, protein expression was observed in fibroblasts at all time point. However, U87MG showed nuclear expression only in cells treated with H2O2, being more evident that in BLM-treated cells. Thus, the observed changes in gene expression profiles are consistent with the induction of DNA damage, which indicates the participation of UPS genes in cellular responses to genotoxic stress. Together, the results encourage further evaluation of these genes as markers of stress response, demonstrating its importance in the UPS acting scope.

1. Estresse Genotóxico

2. Sistema Ubiquitna-Proteassomo

3. Fibroblastos

4. Glioblastoma

5. Marca

1. Genotoxic Stress

2. Ubiquitna-Proteasome System

3. Fibroblasts

4. Glioblastoma

5. Gene Marker

Influência do gene PTEN na expressão de RAD51 e suas parálogas, RAD51C e RAD51B, em linhagens de glioblastoma multiforme tratadas com etoposídeo / PTEN gene Influence in expression of RAD51 and its Paralogs RAD51C and RAD51B, in Glioblastoma strains treated with Etoposide

Ana Clara Oliveira

12 May 2016

O Glioblastoma Multiforme (GBM) é o tipo de tumor cerebral maligno com maior incidência na população. A perda do gene PTEN (fosfatase e tensina homóloga) é uma alteração comum associada ao GBM (até 60%) e esse gene codifica uma enzima que antagoniza a ação de PI3K, inibindo a fosforilação de AKT e, desse modo, regulando vias de sinalização relativas à sobrevivência celular e proliferação. Mutações em PTEN têm sido associadas à instabilidade genômica e ao aumento no número de quebras de fita dupla, além de serem relacionadas também à redução da expressão de RAD51, a qual é uma proteína-chave da via de reparo por recombinação homóloga (HR). Diante disso, o objetivo deste estudo foi avaliar se o status de PTEN interfere na expressão de RAD51 e proteínas parálogas (RAD51C e RAD51B) e, consequentemente, se PTEN é capaz de influenciar a eficiência de HR. Com o objetivo de induzir a formação de quebras de fita duplas (DSBs) no DNA, as células foram tratadas com a droga antitumoral etoposídeo, que produz quebras no DNA, principalmente duplas (DSBs). Duas linhagens de GBM com status diferentes de PTEN foram utilizadas: T98G (PTEN mutado) e LN18 (PTEN tipo selvagem). As células de GBM foram tratadas com etoposídeo em diferentes experimentos ou ensaios: proliferação celular, quantificação da necrose e apoptose, cinética do ciclo celular, imunofluorescência da proteína ?- H2AX, quantificação dos níveis de expressão de RAD51 e parálogas e o silenciamento de PTEN na linhagem LN18. Os resultados mostraram que a linhagem LN18 foi mais sensível à droga nos tempos iniciais (24 e 72 h) (até 61,2% de redução), em comparação com a T98G (até 12,3% de redução); no tempo mais tardio de análise (120 h), ambas as linhagens sofreram redução acentuadana proliferação. Adicionalmente, a LN18 exibiu maior porcentagem de células apoptóticas e necróticas, em comparação com a linhagem T98G, nos tempos de24, 72 e 120 horas após o tratamento. O ensaio de imunofluorescência revelou maior indução de células positivas para ?-H2AX na linhagem LN18 em relação à T98G (p =<0,001), após tratamento com etoposídeo (50 e 75 ?M). Nessas concentrações, a análise da cinética do ciclo celular mostrou um bloqueio na fase G2 em ambas as linhagens (p<0,01) nos tempos analisados (24, 48 e 72h), mas apenas a linhagem LN18 revelou bloqueio na fase S. A expressão de RAD51, RAD51B e C foi mais elevada em LN18 em comparação com a T98G e U87MG, nas células tratados (75?M) e controles. PTEN foi silenciado (siRNA-PTEN) na linhagem LN18 para verificar se a redução da expressão desse gene reduziria também a expressão de RAD51 e parálogas. Após 72 horas de silenciamento, com 69,9% de inibição de PTEN, a expressão de RAD51 e RAD51C também se mostrou reduzida em relação ao grupo controle. Em conjunto, os resultados obtidos no presente estudo indicam que o status de PTEN é crucial para as vias de sobrevivência, controle do ciclo celular e indução de apoptose nas células de GBM, indicando a relação entre PTEN e RAD51 e parálogas nas células de GBM tratadas com um indutor de quebras no DNA. Adicionalmente, outras ferramentas de estudo são requeridas para investigar as vias moleculares e possíveis interações e complexos proteicos envolvendo a participação de PTEN e RAD51 e suas proteínas parálogas / Glioblastoma multiforme (GBM) is the most common malignant brain tumor. Loss of PTEN (Phosphatase and tensin homolog deleted on chromosome 10) gene is the most frequent alteration associated with GBM and encodes a phosphatase enzyme that antagonizes the PI3K, by inhibiting AKT phosphorylation thereby regulating signaling pathways related to cell survival and proliferation. PTEN deficiency has been associated with genomic instability and increased endogenous DSBs, as well as reduced expression of RAD51, which is a key gene with crucial role in HR. In this study, we aimed to evaluate whether the PTEN status in GBM cell lines can affect RAD51 expression and HR efficiency under conditions of treatment with the antineoplastic drug etoposide, which targets the DNA topoisomerase II enzyme, thus leading to the production of DNA breaks. T98G (PTEN mutated) and LN18 (PTEN wild-type) cells were treated with etoposide, and several assays were carried out: cell proliferation, detection and quantification of necrosis and apoptosis, cell cycle kinetics, immunofluorescence staining, RAD51 (and paralogs) protein expression, and PTEN silencing in LN18 cell line, by using the siRNA method. LN18 cells showed a greater reduction in cell proliferation, compared to T98G after treatments (25, 50, 75 e 100 µM) at 24, 72 and 120h. Both cell lines showed a significant increase (p=<0.001) in cell death induction, but LN18 presented a greater percentage of apoptotic and necrotic cells than T98G (24, 72 and 120h). The induction of DSB was analyzed by immunostaining (with ?-H2AX antibody), and for the concentrations (50 and 75 µM) tested, LN18 showed higher levels of ?-H2AX positive cells than that observed for T98G (p=<0.001). The analysis of cell cycle kinetics performed for cells treated with etoposide (50 and 75 µM) and collected at 24, 48 and 72h, LN18 presented a greater G2-blockage, as compared to T98G; only LN18 showed a blockage at the S-phase. The expression of RAD51, RAD51B and C was higher in LN18 compared to T98G and U87MG cells treated with etoposide (75 µM) and controls. When we silenced PTEN in LN18 linage, to check if PTEN silencing may reduce the expression of RAD51 and its paralogs, we found a 69.9% reduction in PTEN protein expressions, and the expression of RAD51 and RAD51C was also found reduced, compared to the control group. Taken together, the results obtained in this study indicate that the status of PTEN is critical for survival pathways, cell cycle control and induction of apoptosis in GBM cells, confirming the relationship between PTEN and RAD51 and its paralogs in GBM cells treated with an inducer of DNA breaks. These results contribute with relevant information for further studies on molecular pathways underlying the interaction between PTEN and RAD51 and its paralogs

glioblastoma

parálogas de RAD51

PTEN

quebras de fita dupla

RAD51

reparo por recombinação homóloga

DNA double strand breaks

Glioblastoma

homologous recombination repair

PTEN

RAD51

RAD51 paralogs

Detalhamento funcional do papel de CD99 em astrocitomas / Functional detailing of CD99 role in astrocitomas

Laís Cavalca Cardoso

20 July 2018

O glioblastoma (GBM) é o tumor cerebral maligno mais comum e agressivo em adultos. Uma combinação de terapia padrão com outras terapias baseadas no conhecimento de sua biologia é necessária para melhorar a sobrevida de pacientes com GBM. Muitos estudos foram desenvolvidos em busca de proteínas de membrana expressas em GBM, pois são potenciais alvos para imunoterapia. A proteína transmembrânica CD99 foi descrita como altamente expressa em astrocitomas de diferentes graus de malignidade. Embora seu mecanismo de ação ainda não seja totalmente compreendido, CD99 está envolvido na adesão e migração celular em diferentes tipos de tumores. O gene CD99 codifica duas proteínas distintas, denominadas isoforma 1, maior, de 32 kDa, e isoforma 2, gerada por splicing alternativo e menor, de 28 kDa. No presente estudo, foi demonstrada a expressão predominante da isoforma 1 em astrocitomas de diferentes graus de malignidade em comparação com o cérebro normal, bem como na linhagem celular de GBM humano U87MG. O transcriptoma das células U87MG transfectadas com siRNA para CD99 foi analisado em relação ao controle. Um total de 2.670 genes diferencialmente expressos foi identificado. Uma análise de enriquecimento no banco de dados DAVID revelou os seguintes processos como os mais significativos: junções aderentes célula-célula; adesão célula-célula envolvendo ligação de caderina e adesão celular. Ensaios funcionais baseados nestes achados (migração, invasão e adesão) foram realizados com células U87MG após o silenciamento de CD99 com dois shRNAs diferentes. A eficiência de silenciamento foi de 80 e 97%, para o shCD991 e 2, respectivamente, confirmada a nível de expressão do gene e da proteína. O silenciamento de CD99 reduziu a migração e invasão para ambos os shRNAs, com diminuição mais acentuada da migração para o shCD99 2, com maior nível de silenciamento de CD99. No ensaio de adesão, a linhagem U87MG shCD99 1 apresentou propriedades adesivas mais baixas que o controle, enquanto o shCD99 2 apresentou resultado oposto, com maior adesão celular do que seu controle. Provavelmente o silenciamento de CD99 afetou a redução da adesão celular em um padrão distinto, sugerindo que o resultado pode ser dependente do nível de expressão remanescente de CD99. Além disso, o CD99 e a faloidina colocalizaram nos lamelipódios e filopódios, sugerindo um papel importante no rearranjo do citoesqueleto. Foi demostrado, ainda, que o silenciamento de CD99 levou à redução da proliferação celular in vitro e diminuição do tumor in vivo. Camundongos imunodeficientes nos quais foram implantadas células silenciadas no cérebro apresentaram uma maior sobrevida que os animais que receberam células controle. A via de sinalização pela qual CD99 modula a proliferação no GBM ainda precisa ser elucidada. Migração, invasão e proliferação são as principais características do GBM que limitam uma ressecção cirúrgica completa e, consequentemente, levam frequentemente à recorrência. Portanto, análises posteriores das vias ativadoras do CD99 no contexto da migração, invasão, proliferação celular e apoptose são válidas para revelar novas estratégias terapêuticas para limitar a progressão do GBM / Glioblastoma (GBM) is the most common and aggressive malignant brain tumor in adults. A combination of standard therapy with other biologically based therapies is necessary to improve the survival of patients with GBM. Many studies have been developed in pursuit of expressed membrane proteins in GBM, which are potential targets for immunotherapy. The transmembrane protein CD99 is highly expressed in different malignant grades of astrocytomas. Although its mechanism of action is not still fully understood, CD99 is involved in cell adhesion and migration in different type of tumors. The CD99 gene encodes two distinct transmembrane proteins, named isoform 1, longer with 32 kDa, and isoform 2, generated by alternative splicing, shorter with 28 kDa. In the present study, we demonstrated predominant expression of isoform 1 in astrocytomas of different malignant grades compared to normal brain, and in the human GBM cell line U87MG. The transcriptome of U87MG cell line transfected with siRNA for CD99 was analyzed in relation to control. A total of 2.670 differentially expressed genes were identified. An enrichment analysis by DAVID Bioinformatics Database revealed the following processes as the most significant: cell-cell adherens junction; cadherin binding involved in cell-cell adhesion and cell-cell adhesion. Functional assays based on these findings (migration, invasion and adhesion) were performed with U87MG cells after knocking down CD99 with two different shRNAs. The CD99 silencing efficiency was 80 and 97%, for shCD99 1 and 2, respectively, confirmed at gene and protein level. The CD99 knockdown reduced migration and invasion for both shRNA, with the highest decrease of migration observed in the higher CD99 knocked down cells. In adhesion assay, shCD99 1 U87MG showed lower adhesive properties than the control, whereas shCD99 2 cells presented opposite results, with higher cell adhesion than control. Probably CD99 knockdown affected in the reduction of cell adhesion in a distinct pattern, suggesting that the result is dependent on CD99 remaining expression level. Additionally, CD99 and phalloidin colocalized at lamellipodia and filopodia, sugesting that CD99 plays an important role to cytoskeleton rearrangement. It has also been demonstrated that CD99 silencing caused reduction of cell proliferation in vitro and decreased tumor in vivo. Immunodeficient mice in which knocked down cells were implanted in the brain had a longer survival than animals that received control cells. The signaling pathway by which CD99 modulates proliferation in GBM still needs to be elucidated. Migration, invasion and proliferation are major characteristics of GBM, which limits the complete surgical tumor resection, and consequently leads to tumor recurrence. Therefore, further analysis of CD99 activating pathways in the context of cell migration, invasion, proliferation and apoptosis is worthwhile to unveil new therapeutic strategies to halt GBM progression

Antígeno CD99

Expressão gênica

Glioblastoma

Inativação gênica

Migração celular

Proliferação celular

Antigens CD99

Cell proliferation

Cell movement

Gene expression

Gene silencing

Glioblastoma

Caractérisation des cellules souches de glioblastomes : nouvelles approches thérapeutiques / Glioblastomas stem-like cells characterization and new therapeutics approaches

Balbous, Anaïs

16 September 2014

Les glioblastomes (GBMs) sont des tumeurs cérébrales au pronostic défavorable. La résistance aux thérapies actuelles et la rechute des GBMs pourraient être due à l'existence de cellules aux propriétés souches. L'objectif de ma thèse a été la caractérisation des cellules souches de GBMs (CSGs) isolées à partir de tumeurs. L'analyse du profil souche et de pluripotence des CSGs a montré qu'elles sont maintenues dans un état souche par SOX2 et que COL1A1 et IFITM1 peuvent être des cibles thérapeutiques potentielles. L'étude de la radiosensibilité des CSGs à travers l'analyse des courbes de clonogénicité a mis en évidence deux groupes dont un «atypique» pouvant être composé de sous-populations de cellules aux radiosensibilités différentes qu'il conviendra de caractériser. L'étude de la réparation a mis en évidence deux autres groupes dont un ayant un fort potentiel de réparation qui exprime plus fortement le gène RAD51 après irradiations. Le traitement par un inhibiteur spécifique de RAD51 ralentirait la capacité de réparation de ces cellules. Malgré cette hétérogénéité, l'inhibition de la voie Hedgehog (HH) par un vecteur glucuronylé de la cyclopamine, activé par le microenvironnement tumoral, inhibe la prolifération et l'auto-renouvellement des CSGs in vitro et ralentit la croissance tumorale in vivo. La voie HH semble être une cible thérapeutique intéressante commune à toutes les CSGs. Néanmoins, il est nécessaire de prendre en compte l'hétérogénéité dans les populations tumorales pour le développement de la médecine personnalisée. / Glioblastomas (GBMs) are brain tumors with a poor prognosis. Their resistance to current therapies and the occurrence of tumor relapse may be related to the existence of cells bearing stem cell characteristics. The aim of this PhD research was to characterize glioblastoma stem cells (GSCs) having been isolated from tumors. Analysis of the stemness and pluripotency profiles of GSCs indicated that their stemness states are maintained by SOX2 and that COL1A1 and IFITM1 may be potential therapeutic targets. Clonogenic studies of GSC radiosensitivity underscored the presence of two groups, one of them composed of sub-populations of cells with different degrees of radiosensitivity that have yet to be fully characterized. Study of DNA repair capacity highlighted two additional groups including one with high repair potential overexpressing the RAD51 gene after 4Gy. However, treatment with RAD51 inhibitor is likely to slow down repair of GSC lesions. Notwithstanding GSC heterogeneity, in our study inhibition of the Hedgehog pathway (HH) by a cyclopamine glucuronid prodrug, activated by the tumor microenvironment, inhibited in vitro proliferation and self-renewal in all the GSCs tested and slowed down tumor growth in vivo. Hence, HH pathway appears to be conserved among GSCs and constitutes an interesting potential therapeutic target. With regard to the development of personalized medicine, it is nevertheless highly advisable to take into account the pronounded heterogeneity of tumor populations.

Glioblastome

Cellules souches de glioblastomes

Radiation ionisantes

Hétérogénéité

Vecteur glucuronylé de la cyclopamine

Rad51

Col1a1

Ifitm1

Glioblastoma

Glioblastoma stem-Like cells

Ionizing radiation

Heterogeneity

Cyclopamine glucuronide prodrug

Rad51

Col1a1

Ifitm1

571.9

Mécanismes moléculaires impliqués dans la plasticité neurovasculaire des cellules souches de glioblastome / Molecular mechanisms involved in glioblastoma stem cell neurovascular plasticity

Guelfi, Sophie

05 December 2016

Les Glioblastomes (GBM, grade IV selon l’OMS) sont les tumeurs cérébrales primaires les plus agressives et sont caractérisées par une néovascularisation importante associée à l’hypoxie et à la nécrose. L’origine cellulaire des GBM est controversée, mais des sous-populations de cellules multipotentes ont été identifiées au sein des tumeurs, et seraient responsables de la radio/chimiorésistance des GBM. Ces cellules souches de glioblastome (GSC) contrôlent activement la vascularisation tumorale par leur interaction étroite avec les cellules vasculaires composant les niches tumorales. La voie Notch est une signalisation canonique essentielle au développement et à l’homéostasie du système nerveux central et son réseau vasculaire associé. Dans le contexte des GBM, cette cascade serait nécessaire à la gliomagénèse, par le maintien du réservoir de GSC au sein de la niche périvasculaire. Cependant, le mode d’action moléculaire de Notch dans les GBM reste encore à démontrer, du fait de résultats divergents observés dans plusieurs études. Dans la première partie de mon travail de thèse, j’ai contribué à l’exploration de la signalisation Notch1 dans des cultures de GSC établies et caractérisées au sein du laboratoire. Le niveau basal d’activation de Notch1 étant faible dans nos GSC, l’approche a été d’activer constitutivement cet axe par transduction lentivirale. Suite à cette activation forcée, les GSC subissent un changement phénotypique majeur et se différencient en cellules périvasculaires ou cellules « pericyte-like ». Cette transition neurovasculaire des GSC promeut la vascularisation active des tumeurs par la normalisation du réseau vasculaire in vivo. Par la suite, j’ai posé la question des mécanismes moléculaires en aval de Notch1 ; par l’étude des facteurs de transcription TAL1 et SLUG, deux candidats potentiels au contrôle de cette plasticité neurovasculaire. Dans ce but, j’ai examiné leur contribution au phénotype vasculaire des GSC dans un modèle in vitro de la niche périvasculaire ; et in vivo par l’analyse d’échantillons humains de GBM. Enfin, j’ai également observé que l’activation de Notch1 module l’activité de la machinerie du protéasome, ce qui pourrait contribuer activement à la transition moléculaire observée dans les GSC. Ces travaux mettent en avant la plasticité phénotypique des GSC: une meilleure compréhension de ces processus pourrait mener à la conception de thérapies ciblant efficacement les GSC et leur vascularisation associée. / Glioblastomas (GBM, WHO grade IV) are highly aggressive brain tumors in which extensive vascularization is associated with hypoxia and necrosis. GBM cell of origin is controversial; however multipotent stem-like subpopulations have been identified within tumors, and could account for GBM radio/chemoresistance. These glioblastoma stem-like cells (GSC) actively promote tumoral vascularization processes by closely interacting with vascular cells composing tumoral niches. The Notch cascade is a canonical signaling pathway required during developmental stages and adult homeostasis of the central nervous system and the associated vascular network. In the context of GBM, this molecular axis could induce gliomagenesis by promoting GSC maintenance in the perivascular niche. However, Notch-induced molecular mechanisms controlling GBM progression still remain elusive, due to divergent results observed in numerous reports. During the first part of my thesis work, I contributed to the assessment of Notch1 functions in GSC cultures isolated and characterized in our lab. Given a low Notch1 basal activation status in our GSCs, our approach was to constitutively activate this axis via lentiviral transduction. Following this forced activation, GSCs undergo drastic phenotypic changes and differenciate into perivascular-like or “pericyte-like” cells. This neurovascular transition of GSCs induces active tumoral vascularization by promoting normalization of the vascular network in vivo. Consequently, I questioned the molecular mechanisms downstream of Notch1 by focusing on TAL1 and SLUG transcription factors, two potential candidates controlling this neurovascular plasticity. For this purpose, I examined their contribution to the GSC vascular-like phenotype in an in vitro model of the perivascular niche; and in vivo by analyzing human GBM samples. Finally, I also observed that Notch1 activation modulates the activity of the proteasomal machinery, which could actively contribute to the molecular transition occurring in GSCs. This work highlights GSC phenotypic plasticity: a better understanding of these processes could lead to the design of therapies efficiently targeting GSCs and their associated vasculature.

Glioblastome

Cellules souches de glioblastome

Vascularisation

Signalisation Notch

Plasticité neurovasculaire

Facteurs de transcription

Glioblastoma

Glioblastoma stem cell

Vascularization

Notch Signaling

Neurovascular plasticity

Transcription factors

A systematic review on the characteristics, treatments and outcomes of the patients with primary spinal glioblastomas or gliosarcomas reported in literature until March 2015

Beyer, Stefanie, von Bueren, André O., Klautke, Gunther, Guckenberger, Matthias, Kortmann, Rolf-Dieter, Pietschmann, Sophie, Müller, Klaus

January 2016

Our aim was to determine the characteristics, treatments and outcomes of patients with primary spinal glioblastomas (GB) or gliosarcomas (GS) reported in literature until March 2015. PubMed and Web of Science were searched for peer-reviewed articles pertaining to cases of glioblastomas / gliosarcomas with primary spinal origin, using predefined search terms. Furthermore we performed hand searches tracking the references from the selected papers. Eighty-two articles published between 1938 and March 2015 were eligible. They reported on 157 patients. Median age at diagnosis was 22 years. The proportion of patients who received adjuvant chemo- or radiotherapy clearly increased from the time before 1980 until present. Median overall survival from diagnosis was 8.0 ± 0.9 months. On univariate analysis age influenced overall survival, whereas tumor location, gender and the extent of initial resection did not. Outcomes did not differ between children (< 18 years) and adults. However, the patients who were treated after 1980 achieved longer survival times than the patients treated before. On multivariable analysis only age (< 60 years) and the time period of treatment (>1980) were confirmed as positive independent prognostic factors. In conclusion, primary spinal GB / GS mainly affect younger patients and are associated with a dismal prognosis. However, most likely due to the increasing use of adjuvant treatment, modest therapeutic progress has been achieved over recent decades. The characteristics and treatments of primary spinal glioblastomas should be entered into a central registry in order to gain more information about the ideal treatment approach in the future.

info:eu-repo/classification/ddc/610

ddc:610

Molecular Mechanisms Associated with Chromosomal and Microsatellite Instability in Sporadic Glioblastoma multiforme

Martinez, Ramon, Schackert, Hans-K., Plaschke, Jens, Baretton, Gustavo, Appelt, Hella, Schackert, Gabriele

January 2004

Objective: Two chromosomal instability (CIN) pathways are described in glioblastoma multiforme (GBM), type 1 and type 2, which can be observed in up to 70% of the cases. Microsatellite instability (MSI) plays a pathogenic role in sporadic cancers such as colon, gastric and endometrial carcinomas with deficient mismatch repair (MMR). We aimed to perform a comprehensive analysis of the relationship between CIN and MSI mechanisms in sporadic glioblastomas. Methods: 129 GBMs were examined (109 newly diagnosed and 20 relapses) investigating MSI, immunohistochemical expression of MMR proteins as well as sequencing and promoter methylation of hMLH1. We characterized the molecular changes frequently correlated with CIN in MSI+ GBMs and compared them with 26 microsatellite-stable tumors. Results: Low-level MSI was observed in 11 of 129 (8.5%) cases and was higher in relapses than in primary GBMs (25 vs. 5.5%, p = 0.027). High-level MSI was not found in any case. A deficient expression of MLH1 and PMS2 without hMLH1 inactivation was observed only in one giant cell GBM. 55% of the MSI+ GBMs showed a profile which did not correspond to one of the known CIN pathways. An inverse association was observed between MSI and mutations of both p53 and PTEN. Conclusions: Our data suggest that CIN and MSI contribute to the genomic instability in GBMs via independent pathways. Since MSI was significantly more frequent in relapses, it might play a role in the malignant progression of GBM. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

info:eu-repo/classification/ddc/610

ddc:610

Der Metabolismus aromatischer Aminosäuren als potentieller Aktivator des Arylhydrocarbon Rezeptors und dessen Auswirkungen auf die Immunantwort

Loth, Stefanie

29 July 2020

In dieser Arbeit wurde die Rolle der L-Aminosäureoxidase IL4I1 für die Progression von Glioblastomen analysiert. IL4I1 wird in diesem Hirntumor erhöht exprimiert und führt dadurch zu einem Abbau der drei aromatischen Aminosäuren Tryptophan (Trp), Phenylalanin und Tyrosin zu ihren entsprechenden α-Ketosäuren (Pyruvaten). In-vitro-Versuche mit IL4I1-überexprimierenden Glioblastomzelllinien zeigen, dass nur das aus Trp-gebildete Indol-3-pyruvat (I3P) bzw. dessen nachgeschaltete Abbauprodukte eine Aktivierung des Arylhydrocarbon Rezeptors (AHR) und seiner Signaltransduktion in Glioblastomen bewirkt. Des Weiteren wurde der Einfluss von IL4I1 in der Tumor-Mikroumgebung auf die Kompetenz von T-Zellen charakterisiert. Das von den Tumorzellen gebildete und sezernierte I3P vermittelt eine Aktivierung des AHR in beiden T-Zellsubpopulationen. Damit einhergehend werden zwei Mechanismen ausgelöst, die die Tumorprogression fördern: eine Proliferationsinhibierung CD8+ zytotoxischer T-Zellen und eine vermehrte Differenzierung immunsuppressiver Treg.

info:eu-repo/classification/ddc/570

ddc:570

Hirntumor

Tryptophan

Glioblastom

Radiomics analyses for outcome prediction in patients with locally advanced rectal cancer and glioblastoma multiforme using multimodal imaging data

Shahzadi, Iram

13 November 2023

Personalized treatment strategies for oncological patient management can improve outcomes of patient populations with heterogeneous treatment response. The implementation of such a concept requires the identification of biomarkers that can precisely predict treatment outcome. In the context of this thesis, we develop and validate biomarkers from multimodal imaging data for the outcome prediction after treatment in patients with locally advanced rectal cancer (LARC) and in patients with newly diagnosed glioblastoma multiforme (GBM), using conventional feature-based radiomics and deep-learning (DL) based radiomics. For LARC patients, we identify promising radiomics signatures combining computed tomography (CT) and T2-weighted (T2-w) magnetic resonance imaging (MRI) with clinical parameters to predict tumour response to neoadjuvant chemoradiotherapy (nCRT). Further, the analyses of externally available radiomics models for LARC reveal a lack of reproducibility and the need for standardization of the radiomics process. For patients with GBM, we use postoperative [11C] methionine positron emission tomography (MET-PET) and gadolinium-enhanced T1-w MRI for the detection of the residual tumour status and to prognosticate time-to-recurrence (TTR) and overall survival (OS). We show that DL models built on MET-PET have an improved diagnostic and prognostic value as compared to MRI.

info:eu-repo/classification/ddc/610

ddc:610

Glioma Stem Cells Adapt to Restricted Nutrition Through Preferential Glucose Uptake

Flavahan, William Alexander

21 February 2014

No description available.

Biology

Biomedical Research

Molecular Biology

Neurobiology

Cellular Biology

cancer

glioblastoma

glioma

cancer stem cells

glioblastoma stem cells

glucose

glucose uptake

GLUT3