The interaction between Hedgehog/Patched and Ras signaling in Rhabdomyosarcoma

Cuvelier, Nicole

07 March 2016

No description available.

610

Rhabdomyosarcoma

RAS signaling

Hedgehog signaling

Rhabdomyosarcoma

RAS signaling

Hedgehog signaling

Medizin (PPN619874732)

La mutation K-RAS détectée dans la marge de résection veineuse d'une pièce de duodénopancréatectomie céphalique définit la notion de "marge génique" et peut modifier la technique chirurgicale

Turrini, Olivier

03 June 2013

La technique d'une DPC pour adénocarcinome a évolué ces dernières années tant au niveau sécurité qu'au niveau carcinologique mais cela n'a pas suffit à faire progresser la survie. On peut se demander si la modification de la technique chirurgicale pourrait avoir un impact significatif sur la survie.A) Nous avons recherché, sur 23 pièces de DPC encrées, la présence de la mutation K-ras au niveau de la marge veineuse affirmée R0 en analyse histologique : 13 spécimens (groupe kras+) exprimaient une mutation K-ras au sein de la marge veineuse versus 10 spécimens (groupe kras-) ne l'exprimant pas. Les tumeurs des 2 groupes étaient comparables (taille, envahissement ganglionnaire, engainement périnerveux…). La survie globale à 1 an et 3 ans des groupes kras- versus kras+ étaient de 80% versus 84,6% et 16,7% versus 0% (p=0,03), respectivement. Les médianes de survie des groupes kras- versus kras+ étaient de 24 mois versus 16 mois (p=0,04), respectivement.B) Nous avons comparé, après appariement, 19 patients ayant eu une DPC avec résection « par excès » de la veine porte (groupe VP) avec 19 patients ayant eu une DPC sans résection de la veine porte (groupe contrôle). Les survies médianes et à 3 ans du groupe VP versus groupe contrôle étaient 42 mois versus 22 mois (p=0,04) et 60% versus 31% (p=0,03), respectivement.En conclusion, notre travail a montré qu'au-delà de la marge déterminée par le chirurgien pendant la chirurgie, de celle de l'anatomopathologiste déterminée par l'analyse microscopique, il existait une marge génique. La résection systématique de la veine porte semblait bénéfique car elle permettait sans doute de passer au-delà de cette marge génique. / Pancreticoduodenectomy (PD) for adenocarcinoma was safer during the last decades but did not improve survival. We sought to determine if technical changes during PD could improve survival.A) In a first study, we determine the presence of K-ras mutation in the venous margin of 23 PD's specimens. Thirteen specimens had K-ras mutation (kras+ group) and 10 specimens did not (kras- group). Except K-ras mutation status, tumors of the 2 groups were not different when comparing major histological findings (margin status, lymph node invasion, perineural invasion…). Overall 1- and 3-years survival of patients of kras- group versus kras+ group were 80% versus 84,6% and 16,7% versus 0% (p=0,03), respectively. Median survival of patients of kras- group versus kras+ group were 24 months versus 16 months (p=0,04), respectively.B) In a second study, we compared 19 patients with “excessive” portal vein resection during PD (PV group) with 19 matched patients who underwent PD without venous resection (control group). Median survival of patients of PV group versus control group were 42 months versus 22 months (p=0,04), respectively.In conclusion, we showed that the « genic margin » concept was consistent. Systematic portal vein resection could avoid positive genic margin and might be benefic for patient who underwent PD for resecable adenocarcinoma.

The Role of Protein-Protein Interactions in the Activation Cycle of RAF Kinases / Die Rolle von Protein-Protein Interaktionen im Aktivierungszyklus der RAF Kinasen

Fischer, Andreas

January 2010

Members of the RAF protein kinase family are key regulators of diverse cellular processes. The need for isoform-specific regulation is reflected by the fact that all RAFs not only display a different degree of activity but also perform isoform-specific functions at diverse cellular compartments. Protein-protein-interactions and phosphorylation events are essential for the signal propagation along the Ras-RAF-MEK-ERK cascade. More than 40 interaction partners of RAF kinases have been described so far. Two of the most important regulators of RAF activity, namely Ras and 14-3-3 proteins, are subject of this work. So far, coupling of RAF with its upstream modulator protein Ras has only been investigated using truncated versions of RAF and regardless of the lipidation status of Ras. We quantitatively analyzed the binding properties of full-length B- and C-RAF to farnesylated H-Ras in presence and absence of membrane lipids. While the isolated Ras-binding domain of RAF exhibit a high binding affinity to both, farnesylated and nonfarnesylated H-Ras, the full-length RAF kinases demonstrate crucial differences in their affinity to Ras. In contrast to C-RAF that requires carboxyterminal farnesylated H-Ras for interaction at the plasma membrane, B-RAF also binds to nonfarnesylated H-Ras in the cytosol. For identification of the potential farnesyl binding site we used several fragments of the regulatory domain of C-RAF and found that the binding of farnesylated H-Ras is considerably increased in the presence of the cysteine-rich domain of RAF. In B-RAF a sequence of 98 amino acids at the extreme N terminus enables binding of Ras independent of its farnesylation status. The deletion of this region altered Ras binding as well as kinase properties of B-RAF to resemble C-RAF. Immunofluorescence studies in mammalian cells revealed essential differences between B- and C-RAF regarding the colocalization with Ras. In conclusion, our data suggest that that B-RAF, in contrast to C-RAF, is also accessible for nonfarnesylated Ras in the cytosolic environment due to its prolonged N terminus. Therefore, the activation of B-RAF may take place both at the plasma membrane and in the cytosolic environment. Furthermore, the interaction of RAF isoforms with Ras at different subcellular sites may also be governed by the complex formation with 14-3-3 proteins. 14-3-3 adapter proteins play a crucial role in the activation of RAF kinases, but so far no information about the selectivity of the seven mammalian isoforms concerning RAF association and activation is available. We analyzed the composition of in vivo RAF/14-3-3 complexes isolated from mammalian cells with mass spectrometry and found that B-RAF associates with a greater variety of 14-3-3 proteins than C- and A-RAF. In vitro binding assays with purified proteins supported this observation since B-RAF showed highest affinity to all seven 14-3-3 isoforms, whereas C-RAF exhibited reduced affinity to some and A-RAF did not bind to the 14-3-3 isoforms epsilon, sigma, and tau. To further examine this isoform specificity we addressed the question of whether both homo- and heterodimeric forms of 14-3-3 proteins participate in RAF signaling. By deleting one of the two 14-3-3 isoforms in Saccharomyces cerevisiae we were able to show that homodimeric 14-3-3 proteins are sufficient for functional activation of B- and C-RAF. In this context, the diverging effect of the internal, inhibiting and the activating C-terminal 14-3-3 binding domain in RAF could be demonstrated. Furthermore, we unveil that prohibitin stimulates C-RAF activity by interfering with 14-3-3 at the internal binding site. This region of C-RAF is also target of phosphorylation as part of a negative feedback loop. Using tandem MS we were able to identify so far unknown phosphorylation sites at serines 296 and 301. Phosphorylation of these sites in vivo, mediated by activated ERK, leads to inhibition of C-RAF kinase activity. The relationship of prohibitin interference with 14-3-3 binding and phosphorylation of adjacent sites has to be further elucidated. Taken together, our results provide important new information on the isoform-specific regulation of RAF kinases by differential interaction with Ras and 14-3-3 proteins and shed more light on the complex mechanism of RAF kinase activation. / RAF Protein Kinasen sind essentielle Regulatoren verschiedener zellulärer Prozesse. Unterschiedlich starke Aktivitäten und Lokalisation der drei RAF Isoformen erfordern eine isoform-spezifische Regulation. Der Einfluss von Protein-Protein Interaktionen und Phosphorylierungen ist dabei mitentscheidend für die Signalweiterleitung entlang der Ras-RAF-MEK-ERK Kaskade. Mehr als 40 Interaktionspartner der RAF Kinasen wurden bereits beschrieben von denen zwei der wichtigsten, Ras und 14-3-3 Proteine, Gegenstand der vorliegenden Arbeit sind. Die Interaktion von RAF mit seinem vorgeschaltetem Modulatorprotein Ras wurde bislang nur mit verkürzten RAF-Proteinen und ohne Rücksicht auf den Lipidierungsgrad von Ras untersucht. Wir haben die Bindeeigenschaften von B- und C-RAF in voller, nativer Länge zu farnesyliertem H-Ras in Gegenwart und Abwesenheit von Membranlipiden quantifiziert. Während die isolierte Ras-Bindungsdomäne eine hohe Affinität sowohl zu farnesyliertem als auch nicht-farnesyliertem H-Ras aufweist, zeigen die RAF Proteine in voller Länge entscheidende Unterschiede in ihrem Bindeverhalten zu Ras. C-RAF benötigt für eine effiziente Interaktion mit H-Ras dessen C-terminale Farnesylgruppe, wobei B-RAF auch an nicht-farnesyliertes H-Ras im Cytosol bindet. Um die verantwortliche Farnesylbinderegion zu identifizieren haben wir verschiedene Fragmente der regulatorischen Domäne von C-RAF eingesetzt. Dadurch konnten wir zeigen, dass die Affinität zu farnesyliertem Ras in Gegenwart der sogenannten Cystein-reichen Domäne von RAF beträchtlich erhöht war. In B-RAF ist eine Sequenz von 98 Aminosäuren am N-Terminus verantwortlich für die Ras-Bindung unabhängig von dessen Farnesylierungszustand. Die Deletion dieser Sequenz von B-RAF veränderte die Ras-Bindungseigenschaften sowie die Kinaseaktivität vergleichbar mit C-RAF. Durch Immunfluoreszenzversuche in Säugerzellen konnten darüber hinaus Unterschiede in der Kolokalisation von B- und C-RAF mit Ras beobachtet werden. Zusammenfassend deuten unsere Ergebnisse darauf hin, dass B-RAF, im Gegensatz zu C-RAF, aufgrund seines verlängerten N-Terminus in der Lage ist bereits im Cytosol auch mit unfarnesyliertem Ras zu interagieren, wodurch die Aktivierung von B-RAF sowohl im Cytosol als auch an der Plasmamenbran erfolgen kann. Die Interaktion der RAF-Isoformen mit Ras in unterschiedlichen zellulären Kompartimenten kann aber auch durch die Komplexbildung mit 14-3-3 Proteinen beeinflusst werden. Die 14-3-3 Adapter Proteine spielen eine entscheidende Rolle im Aktivierungszyklus der RAF Proteine. Bislang waren jedoch keine Details bezüglich der Selektivität der sieben 14-3-3 Isoformen aus Säugerzellen hinsichtlich der Assoziation mit und Aktivierung der RAF Kinasen bekannt. Wir haben RAF/14-3-3 Komplexe aus Säugerzellen isoliert und durch Massenspektrometrie analysiert. Dadurch konnten wir zeigen, dass B-RAF mit einer größeren Vielfalt an 14-3-3 Isoformen bindet als C- und A-RAF. In vitro Bindungsversuche mit gereinigten Proteinen bestätigten die höhere Affinität von B-RAF zu allen sieben Säuger-14-3-3 Proteinen. C-RAF dagegen zeigte eine deutlich reduzierte Affinität, während für A-RAF keine Bindung zu den 14-3-3 Isoformen epsilon, sigma, und tau festgestellt wurde. Um diese Isoformspezifität weiter aufzuklären haben wir untersucht, ob sowohl Homo- als auch Heterodimere von 14-3-3 in der Lage sind die RAF-Signaltransduktion zu beeinflussen. Durch die Deletion einer der beiden 14-3-3 Isoformen aus Saccharomyces cerevisiae konnten wir zeigen, dass bereits ein 14-3-3 Homodimer für die korrekte Aktivierung von B- und C-RAF ausreichend ist. In diesem Zusammenhang konnte auch die Rolle der internen, inhibierenden 14-3-3 Bindestelle in RAF gegenüber der C-terminalen, aktivierenden Stelle dargelegt werden. Zusätzlich zeigen wir, dass Prohibitin seinen aktivierenden Einfluss gegenüber C-RAF durch die Beeinträchtigung der 14-3-3 Bindung an der internen Stelle in RAF ausübt. Diese Region in C-RAF ist das Ziel von Phosphorylierungen im Zuge eines negativen Rückkopplungsmechanismus. Durch den Einsatz von Tandem-Massenspektrometrie konnten wir bislang unbekannte Phosphorylierungsstellen an den Serinen 296 und 301 identifizieren deren ERK-vermittelte Phosphorylierung in vivo eine Inaktivierung der C-RAF bewirkt. Der Zusammenhang zwischen der Behinderung der 14-3-3 Anlagerung durch Prohibitin und die Phosphorylierung in unmittelbarer Nachbarschaft bedarf weiterer Untersuchungen. Zusammengefasst liefern unsere Ergebnisse wichtige Informationen bezüglich der isoform-spezifischen Regulation der RAF Kinasen durch die Interaktion mit Ras und 14-3-3 Proteinen und helfen die komplexen Mechanismen der RAF Aktivierung weiter aufzuklären.

Signaltransduktion

Raf <Biochemie>

Biochemie

Ras

H-ras

ddc:570

O papel da autofagia no estresse oncogênico promovido por HRASG12V em queratinócitos humanos imortalizados por E6E7 / The role of autophagy in the face of the oncogenic stress triggered by HRASG12V in human keratinocytes immortalized by E6E7

Lopes-Cararo, Eduardo

12 May 2017

RAS é a oncoproteína mutada mais encontrada em tumores sólidos, o que mostra seu grande potencial transformador. Não obstante, células que carregam essa mutação apresentam estresse oncogênico gerado por excessiva sinalização mitogênica, o que direciona preferencialmente as células portadoras para a morte em detrimento da transformação maligna. Basicamente a transformação direcionadapela proteína RAS mutada age sinergicamente com deficiência em supressores de tumor para evitar o destino celular preferencial frente ao estresse oncogênico. Este é o caso da interação observada entre HRASG12V e E6E7 de HPV, sendo que a infecção pelo vírus aparentemente é condição necessária em cânceres cervicais e muito presente em cânceres de cabeça e pescoço. A sinergia entre HRASG12V e queratinócitos imortalizados por E6E7 desequilibra o balanço homeostático entre subsistemas pró-morte, devido ao estresse oncogênico, ou pró-sobrevivência, que garante viabilidade por meio de novos padrões de robustez celular. Em ambos os casos, o processo que gera uma célula transformada, ou as elimina pelo caminho, apresenta pistas de vulnerabilidades às quais os queratinócitos são expostos uma vez que carreguem tal combinação de fatores. Apresentamos nesse trabalho os principais atores que compõem o estresse oncogênico deletério desencadeado pela atividade de HRASG12V: estresse mitogênico, replicativo e oxidativo; todos eles são responsáveis por provocar dano no DNA, que por sua vez promove parada no ciclo celular até que as células não possam mais suportar tamanha injúria, o que acaba levando-as maciçamente a morte. Mostramos que a alta intensidade mitogênica gerada pela atividade de HRASG12V provoca um desequilíbrio metabólico que leva ao aumento de espécies oxidantes e ao estresse replicativo. Todavia, um tratamento exógeno com o antioxidante NAC restaurou parcialmente a proliferação celular assim como a sobrevivência, agindo como um amenizador do dano no DNA gerado pelas espécies oxidantes. Já uma suplementação com nucleosídeos exógenos restaurou fortemente a sobrevivência celular, sugerindo que o desequilíbrio metabólico pode estar agindo no pool de nucleotídeos, o que poderia ser uma das causas do estresse replicativo. Como mecanismo intrínseco de sobrevivência, a autofagia se intensifica em resposta ao desequilíbrio sistêmico desencadeado pela atividade de HRASG12V. Por meio de sublinhagens defectivas para autofagia, mostramos que o processo retarda o aparecimento de espécies oxidantes, além de evitar sua elevação a níveis ainda mais drásticos, o que consequentemente ameniza o dano no DNA observado. Além disso, hipotetizamos que o processo poderia também estar contribuindo fortemente para a reciclagem de substratos básicos tais como nucleotídeos, assim acarretando em menor estresse replicativo. Na literatura atual, debate-se a noção de que, dependendo do contexto celular, a autofagia poderia promover tanto morte celular como transformação maligna. Entretanto, nesta tese mostramos que, na interação entre queratinócitos, E6E7 e HRASG12V, a autofagia é um mecanismo pró-sobrevivência: se por um lado a demanda autofágica é recrutada além de sua capacidade de processamento, fazendo com que seu fluxo seja bloqueado, por outro a eliminação do sistema se torna demasiadamente deletério, direcionando as células expostas ao estresse oncogênico causado pela atividade de HRASG12V necessariamente à morte. / Mutated RAS is the oncoprotein most found in solid tumors, which shows its huge tumorogenic potential. Despite of that, mutated RAS triggers a strong oncogenic stress, which very often drives cells to death instead of malignant transformation. Basically, the success of the Ras malignant transformation driving activity depends on a synergy between that mutated protein and inhibition of tumor suppression genes. This is the case of the interaction between HRASG12V and E6E7 proteins of HPV: It seems that HPV infection is an initial necessary condition for cervical cancer development and is also very frequent in head and neck carcinomas. The synergy between HRASG12V and E6E7, in pre-malignant keratinocytes, imbalances the homeostasis between pro-death subsystems, due oncogenic stress, and pro-survival subsystems that ensure new patterns of cellular robustness. In both cases, the process responsible for generating a malignant transformed cell or, more frequently, eliminating those cells carrying the combined characteristics, exposes the keratinocytes vulnerabilities. We showed in this work that the main actors of deleterious oncogenic stress triggered by HRASG12V activity are: Mitogenic, replicative and oxidative stresses; all of them induce DNA damage, hence cell cycle arrests until the cell cannot resist such injury any further, which leads to massive cell death. The intense mitogenic activity triggered by HRASG12Vcauses metabolic imbalance, which is responsible for an increase of oxidative species and replicative stress levels; the exogenous treatment with antioxidant NAC partially restored cell growth and cell survival, acting as a softener of the DNA damage caused by oxidative species. On the other hand, nucleoside supplementation strongly restored cell survival, suggesting that the aforementioned metabolic imbalance might be acting in the pool of nucleotides, hence it might be a possible cause of replicative stress. As an intrinsic survival mechanism, the autophagy is intensified in response to systemic imbalance triggered by HRASG12V activity. Through the autophagy defective subline, we showed that that mechanism both delays the increase of oxidative species and avoids their elevation to catastrophic highlevels. Furthermore, autophagy could strongly contribute to the recycling of basic substrates such as nucleotides, which might be mitigating the replicative stress. Nowadays, there is a debate on the role of autophagy promoting either malignant transformation or cell death depending on metabolic context. In this work, we showed an instance of the interaction between E6E7 and HRASG12V triggering autophagy pro-survival mechanisms and hence increasing general cell viability

Autofagia

Autophagy

E6E7

E6E7

Estresse Oncogênico

Keratinocytes

Oncogenic stress

Queratinócitos

RAS

Ras

Mecanismos moleculares do efeito citotóxico de FGF2 em células transformadas por RAS / Molecular mechanisms of the cytotoxic effect of FGF2 in rastransformed cells

Fonseca, Cecilia Sella

04 July 2018

O FGF2 (Fibroblast Growth Factor 2) é um clássico fator peptídico de crescimento que ativa vias intracelulares de sinalização molecular promovendo a transição G0 &#8594; G1 e o comprometimento com o ciclo celular. Não surpreendentemente, seus papéis pró-tumoral e angiogênico estão bem caracterizados e estabelecidos na literatura. No entanto, um crescente corpo de evidências tem indicado que o FGF2 também pode exercer efeitos anti-tumorais in vitro e in vivo, em modelos murinos e também humanos. Neste contexto, nosso grupo publicou em 2008 que o FGF2 exerce um efeito antiproliferativo seletivo em células murinas malignas dependentes de alta atividade de K-Ras e H-Ras. Os genes ras compõem a família de oncogenes mais frequentemente mutada em tumores malignos humanos, alcançando aproximadamente 30% de todos os casos. O desenvolvimento de terapias contra tumores dependentes de Ras fracassou, apesar dos intensos esforços e investimentos desde a descoberta em 1982 de suas mutações ativadoras em múltiplos cânceres. O objetivo deste trabalho foi desvendar os mecanismos moleculares pelo quais o FGF2 inibe irreversivelmente a proliferação de células malignas dependentes da atividade de Ras, empregando como modelos experimentais a linhagem murina Y1 de células adrenocorticais, e 4 linhagens humanas derivadas de sarcomas de Ewing. Identificamos que o efeito citotóxico do FGF2 não se processa por um mecanismo novo e independente das viasproliferativas classicamente ativadas por fatores peptídicos de crescimento. Ao contrário, seu efeito tóxico é resultado de sinalização mitogênica exagerada decorrente de estimulação sustentada por FGF2. A ativação da via de MAPK, principal sinalização mitogênica intracelular, a níveis elevados e sustentados provoca estresse mitogênico, que se propaga para a fase S na forma de estresse replicativo. Nesta situação, a célula passa a depender exageradamente da sinalização protetora de ATR, de modo que a combinação de estimulação com FGF2 e inibição de ATR foi altamente letal para as células malignas dependentes de Ras empregadas neste trabalho. Também analisamos as bases moleculares de resistência a FGF2 exibida por células Y1 anteriormente selecionadas para resistir ao efeito tóxico do FGF2 (Y1FRs). Descobrimos que a pressão seletiva do FGF2 não teve efeito na expressão de seus receptores, mas provocou a eliminação de um dos dois cromossomos que portam a amplificação gênica de ras nesta linhagem, enquanto o segundo cromossomo foi mantido por ser a única fonte de genes ribossomais ativos. Suas cópias de ras, no entanto, mostraram-se transcricionalmente silenciadas. Além disso, as sublinhagens Y1FRs não expressam o principal RasGEF, GRP4, encontrado nas células parentais Y1, o que pode ter influenciado o surgimento do fenótipo resistente ao FGF2. As linhagens resistentes mostraram grande redução no número de cromossomos e aumento da frequência de fusões entre cromossomos não homólogos em relação às células parentais. / FGF2 (Fibroblast Growth Factor 2) is a classic peptide growth factor that activates intracellular molecular signaling pathways promoting the G0 &#8594; G1 transition and cell cycle commitment. Not surprisingly, its pro-tumor and angiogenic roles are well characterized and established in the literature. However, a growing body of evidence has indicated that FGF2 may also exert anti-tumor effects in vitro and in vivo in murine and human models. In this context, our group reported in 2008 that FGF2 exerts a selective antiproliferative effect in murine cells dependent on high activity of K-Ras and H-Ras. Ras genes make up the most frequently mutated oncogene family in human malignant tumors, reaching approximately 30% of all cases. The development of therapies against Ras-dependent tumors has failed despite intense efforts and investments since the discovery in 1982 of its activating mutations in multiple cancers. The objective of this work was to uncover the molecular mechanisms by which FGF2 irreversibly inhibits the proliferation of malignant cells dependent on Ras activity, using as experimental models the Y1 murine lineage of adrenocortical malignant cells and 4 human lineages derived from Ewing sarcomas. We showed that the cytotoxic effect of FGF2 did not involve novel cell cycle regulatory pathways; instead, this cytotoxic effect is a result of sustainedhyper mitogenic stimulation by FGF2. Activation of the KRas/MAPK pathway, the major intracellular mitogenic signaling, at high and sustained levels provokes mitogenic stress, which is propagated to S phase as replicative stress. In this situation, the cell dependence on the ATR protective signaling is enhanced, so that the combination of stimulation with FGF2 and inhibition of ATR was highly lethal for the Ras dependent malignant cells employed in this work. We also analyzed the molecular basis of FGF2 resistance exhibited by Y1 cells previously selected for resistance to FGF2. We found that the selective pressure of FGF2 had no effect on the expression of its receptors but promoted the elimination of one of the two marker chromosomes that carry the K-ras amplified copies, while the second chromosome was maintained because it is the only source of active ribosomal genes; however, its K-ras amplified copies were transcriptionally silenced. In addition, the Y1FRs sublines did not express the main RasGEF, GRP4, found in the parental Y1 cells, which might have played a role in the emergence of the FGF2-resistant phenotype. The resistant Y1FRs sublines showed a large reduction in chromosome numbers and increased frequency of fusions between non-homologous chromosomes in relation to parental cells.

ATR

ATR

Estresse replicativo

FGF2

FGF2

MAPK

MAPK

Ras

Ras

Replicative stress

Mecanismos anti-proliferativos disparados por FGF2 e éster de forbol em células de camundongos tranformadas por Ras / Anti-proliferative mechanisms induced by FGF2 and phorbol ester in murine cell lines transformed by Ras

Matos, Tatiana Guimarães de Freitas

17 September 2007

Mutações com ganho de função do proto-oncogene Ras se encontram entre umas das mais freqüentes modificações em cânceres humanos, além disso, tumores com esses caracterísitcas possuem, em geral, mau prognóstico. O objetivo inicial desta tese foi estudar novos mecanismos anti-proliferativos disparados por dois agentesmitogênicos, FGF2 (\"Fibroblast Growth Factor 2\") e PMA (\"Phorbol-12-Myristate-13-Acetate\", (um diéster de forbol), sobre células de camundongos transformadas por Ras e refratárias a apoptose. Para isso utilizamos duas linhagens celulares: uma linhagem naturalmente trtansformada por uma ampliação do gene K-Ras, que é derivada de um tumor de córtex adreno-cortical de camundongo e é denominada Y1, e uma sublinhagem derivada de Balb/c-3T3, transformada em laboratório com o oncogene H-RasV12 humano. A fim de se elucidar o mecanismo de ação de FGF2, foram selecionadas e caracterizadas múltiplas sublinhagens clonais resistentes a FGF2, derivadas das linhagens parentais Y1 e B61. Mostramos assim, que o FGF2 exerce um forte efeito negativo, de forma que os clones resistentes ao mesmo tendem a perder aos altos níveis de expressão da proteína Ras. Mostramos ainda que esses células passam a ser dependentes de FGF2 para crescer em cultura, perdem a capacidade de crescimento em suspensão e são menos tumorigênicas quando comparadas às células parentais. Em uma segunda etapa, caracterizamos o efeito citotóxico de PMA sobre células transformadas por Ras, e vimos que esse efeito é mais acentuado para células transformadas por K-Ras, mas é nulo sobre células imortalizadas não tumorigênicas. Mostramos ainda que esse efeito passa pela ativação da via de PKC. A inibição da proliferação por PMA se deve, ao menos parcialmente, à indução de senescência nessas células. De forma semelhante ao que foi para o estudo com FGF2, foram selecionados clones resistentes a PMA, derivados de Y1. Os clones obtidos se mostraram muito instáveis, pouco resistentes a PMA e dependentes de FGF2 para crescer. Todos os clones testados se mostram tumorigênicos, entretanto, apresentaram maior tempo de latência, estaticamente diferente da célula parental, Y1. Assim, neste trabalho, mostramos que duas substâncias, com caráter mitogênico e potencialmente oncogênico, são capazes de inibir seletivamente a proliferação de células transformadas por Ras, uma vez que elas não têm efeito sobre células não transformadas. Desvendar os mecanismos que causam a citotoxidade dessas substâncias deve trazer informações relevantes com possibilidades de impacto em terapia de tumores dependentes dos oncogenes Ras. / Amplification and gain of function mutations in ras proto-oncogenes are frequent genetic lesions in human cancers of bad prognostic. This thesis aimed to investigate novel anti-proliferative mechanisms induced by two mitogens, FGF2 (\"Fibroblast Growth Factor 2\") and PMA (\"Phorbol-12-Myristate-13-Acetate\", a phorbol diester), in murine cell lines transformed by ras and resistant to apoptosis. To this end, we took two different mouse malignant cell lines: Y1, a cell line derived from an adrenal tumor, naturally transformed by K-ras amplification and another one, 3T3-B61, obtained by transformation of Balb-3T3 fibroblasts with the H-rasV12 oncogene. To elucidate FGF2 mechanisms of action, we selected, isolated and characterized clonal sublines resistant to FGF2 from both Y1 and 3T3-B61 parental lines. FGF2-resistant clones are rare normal-like revertant sublines that no longer display Ras over expression, dependent on FGF2 for growth, do not grow in suspension cultures and exhibit low tumorigenicity in Nude mice. These results show that FGF2 exerts a strong selective pressure against ras-transformed cells, inducing senescence and irreversibly blocking proliferation. Differently from FGF2 , PMA citotoxic effect is completely dependent on PKC activity. In addition, PMA is highly toxic to K-Ras transformed Y1 cells, poorly toxic to H-Ras-transformed 3T3-B61 cells and not toxic to immortalized non tumorigenic cell lines. Attempts to select PMA-resistant cells fropm Y1 parental line have yielded very rare, highly clonal sublines, dependent on FGF2 for proliferation. In conclusion, two mitogens, FGF2 and PMA, can selectively inhibit Ras-driven proliferation, a phenomenon of great interest for biology and therapy of tumors dependent on ras oncogenes.

Cell transformation

FGF2

FGF2

Fisiologia

PMA

PMA

Ras

Ras

Transformação celular

Tumorigênese

Tumorigenesis

Vulnerabilidades específicas de células malignas humanas dependentes de Ras oncogênico: FGF2 e PMA como supressores de tumor / Specific vulnerabilities of human malignant cells dependent on oncogenic Ras: FGF2 and PMA as tumor suppressors

Julianna Dias Zeidler

13 November 2012

Um passo limitante no desenvolvimento de fármacos para terapias do câncer está na descoberta de vulnerabilidades específicas de células tumorais que sirvam à identificação de alvos moleculares apropriados à intervenção farmacológica. Esta é a motivação central desta tese, cuja abordagem experimental focaliza a ação oncogênica das proteínas Ras. Amplificação ou mutação ativadora nos proto-oncogenes ras estão entre as alterações genéticas mais frequentes em cânceres. Essas lesões genéticas aparecem na origem etiológica de múltiplas formas de fenótipos malignos. Mas, essas lesões oncogênicas também conferem susceptibilidades letais às células malignamente transformadas frente a determinados agentes que não interferem significativamente nas funções vitais de células normais. Nos últimos anos nosso laboratório vem estudando os mecanismos moleculares da ação antiproliferativa do fator de crescimento FGF2 (Fibroblast Growth Factor2) e do éster de forbol PMA (Phorbol-12-Myristate-13-Acetate) em linhagens de células murinas malignas dependentes de ras oncogênico. Nesta tese investigamos quanto de nossas observações anteriores com células murinas são aplicáveis a células humanas. Nesse sentido focalizamos a linhagem HaCaT de queratinócitos humanos imortalizados e seus subclones malignizados por expressão ectópica de H-RasV12; além disso, numa triagem inicial também examinamos treze linhagens celulares humanas derivadas de tumores naturais portadores de mutação ativadora em H-Ras, N-Ras ou K-Ras. Nossos resultados mostram que os queratinócitos da linhagem parental HaCaT expressam receptores de FGFs e respondem mitogenicamente tanto a FGF2 como a PMA; portanto, ambos FGF2 e PMA são benéficos aos queratinócitos HaCaT. Por outro lado, o FGF2 mostrou-se citotóxico para subclones HaCaT que expressam H-RasV12 induzível, mas sublinhagens HaCaT com expressão constitutiva de H-RasV12 mostraram-se resistentes à ação citotóxica de FGF2. Diferentemente de FGF2, PMA bloqueou a proliferação de sublinhagens clonais HaCaT-H-RasV12 em ambos substrato sólido e suspensão de agarose e, também, reduziu a estratificação dos queratinócitos HaCaT-H-RasV12 em culturas organotípicas. PMA foi citotóxico e não citostático, pois induziu morte apoptótica sem causar arresto em nenhuma fase específica do ciclo celular. Em HaCaT parental, PMA induziu aumento transitório dos níveis intracelulares de espécies reativas de oxigênio (ROS), mas nos queratinócitos HaCaT-H-RasV12, PMA causou aumentos mais altos e persistentes de ROS, o que promove forte estresse oxidativo, provavelmente responsável pela toxidez deste ester de forbol. Entre as treze linhagens celulares humanas malignas com H-Ras, N-Ras ou K-Ras mutados, onze foram vulneráveis à ação citotóxica de PMA; mas apenas uma delas, a linhagem de tumor urotelial UM-UC-3, foi sensível ao efeito anti-proliferativo de FGF2. Em conclusão, células malignas humanas com Ras mutado parecem superar rapidamente uma possível toxidez de FGF2, mas não ultrapassam a toxidez causada por PMA. / A challenge in drug development for cancer therapy is the discovering of molecular targets suitable for pharmacological interference. This challenge was the main motivation of the present thesis. Amplification or activating mutation in ras proto-oncogenes are among the most frequent genetic lesions in human cancer. Actually, mutated Ras onco-proteins are in the etiological roots of multiple malignant phenotypes; however these onco-proteins also cause specific lethal vulnerabilities even in robust malignant cells. Recently, our laboratory reported that malignant murine cell lines dependent on oncogenic Ras are prone to toxicity initiated by FGF2 (Fibroblast Growth Factor 2) and PMA (Phorbol-12-Myristate-13-Acetate), which are not harmful to normal cells. This cytotoxicity of FGF2 and PMA very likely follows different molecular mechanisms, which, however, are not yet completely understood. The aim of this thesis was to investigate whether these vulnerabilities found in murine malignant cells were also valid for human malignant cell lines dependent on oncogenic Ras. To this end the experimental approach was focused on the HaCaT cell line of immortalized human keratinocytes and its sublines transformed by H-RasV12 ectopic expression. In addition thirteen human cell lines derived from natural tumor carrying mutated H-Ras, N-Ras or K-Ras oncogenes were also screened. The results showed that HaCaT keratinocytes express FGF receptors and respond mitogenically to both FGF2 and PMA. On the other hand, FGF2 was cytotoxic to HaCaT subclones expressing inducible H-RasV12. But, HaCaT sublines constitutively expressing H-RasV12 were resistant to FGF2 toxicity. However, PMA was toxic to all HaCaT-H-RasV12 sublines, inhibiting proliferation in both solid substrate and agarose suspension cultures and, also reducing stratification in organotypic cultures. Furthermore, in HaCaT-H-RasV12 sublines, but not in the parental HaCaT line, PMA caused a persistently high increase in intracellular levels of reactive oxygen species (ROS) and concomitantly induced apoptosis. Moreover, eleven of the thirteen human tumor cell lines with mutated H-Ras, N-Ras or K-Ras, were growth inhibited by PMA, whereas only one of them was inhibited by FGF2, the urothelial tumor cell line UM-UC-3. In conclusion, human malignant cells driven by Ras oncogenes very likely rapidly overcome FGF2 toxicity, whereas they remain stably vulnerable to PMA cytotoxicity.

Citotoxidez

Estresse oxidativo

FGF2

PMA

Ras

Cytotoxicity

FGF2

Oxidative stress

PMA

Ras

Mecanismos moleculares do efeito citotóxico de FGF2 em células transformadas por RAS / Molecular mechanisms of the cytotoxic effect of FGF2 in rastransformed cells

Cecilia Sella Fonseca

04 July 2018

O FGF2 (Fibroblast Growth Factor 2) é um clássico fator peptídico de crescimento que ativa vias intracelulares de sinalização molecular promovendo a transição G0 &#8594; G1 e o comprometimento com o ciclo celular. Não surpreendentemente, seus papéis pró-tumoral e angiogênico estão bem caracterizados e estabelecidos na literatura. No entanto, um crescente corpo de evidências tem indicado que o FGF2 também pode exercer efeitos anti-tumorais in vitro e in vivo, em modelos murinos e também humanos. Neste contexto, nosso grupo publicou em 2008 que o FGF2 exerce um efeito antiproliferativo seletivo em células murinas malignas dependentes de alta atividade de K-Ras e H-Ras. Os genes ras compõem a família de oncogenes mais frequentemente mutada em tumores malignos humanos, alcançando aproximadamente 30% de todos os casos. O desenvolvimento de terapias contra tumores dependentes de Ras fracassou, apesar dos intensos esforços e investimentos desde a descoberta em 1982 de suas mutações ativadoras em múltiplos cânceres. O objetivo deste trabalho foi desvendar os mecanismos moleculares pelo quais o FGF2 inibe irreversivelmente a proliferação de células malignas dependentes da atividade de Ras, empregando como modelos experimentais a linhagem murina Y1 de células adrenocorticais, e 4 linhagens humanas derivadas de sarcomas de Ewing. Identificamos que o efeito citotóxico do FGF2 não se processa por um mecanismo novo e independente das viasproliferativas classicamente ativadas por fatores peptídicos de crescimento. Ao contrário, seu efeito tóxico é resultado de sinalização mitogênica exagerada decorrente de estimulação sustentada por FGF2. A ativação da via de MAPK, principal sinalização mitogênica intracelular, a níveis elevados e sustentados provoca estresse mitogênico, que se propaga para a fase S na forma de estresse replicativo. Nesta situação, a célula passa a depender exageradamente da sinalização protetora de ATR, de modo que a combinação de estimulação com FGF2 e inibição de ATR foi altamente letal para as células malignas dependentes de Ras empregadas neste trabalho. Também analisamos as bases moleculares de resistência a FGF2 exibida por células Y1 anteriormente selecionadas para resistir ao efeito tóxico do FGF2 (Y1FRs). Descobrimos que a pressão seletiva do FGF2 não teve efeito na expressão de seus receptores, mas provocou a eliminação de um dos dois cromossomos que portam a amplificação gênica de ras nesta linhagem, enquanto o segundo cromossomo foi mantido por ser a única fonte de genes ribossomais ativos. Suas cópias de ras, no entanto, mostraram-se transcricionalmente silenciadas. Além disso, as sublinhagens Y1FRs não expressam o principal RasGEF, GRP4, encontrado nas células parentais Y1, o que pode ter influenciado o surgimento do fenótipo resistente ao FGF2. As linhagens resistentes mostraram grande redução no número de cromossomos e aumento da frequência de fusões entre cromossomos não homólogos em relação às células parentais. / FGF2 (Fibroblast Growth Factor 2) is a classic peptide growth factor that activates intracellular molecular signaling pathways promoting the G0 &#8594; G1 transition and cell cycle commitment. Not surprisingly, its pro-tumor and angiogenic roles are well characterized and established in the literature. However, a growing body of evidence has indicated that FGF2 may also exert anti-tumor effects in vitro and in vivo in murine and human models. In this context, our group reported in 2008 that FGF2 exerts a selective antiproliferative effect in murine cells dependent on high activity of K-Ras and H-Ras. Ras genes make up the most frequently mutated oncogene family in human malignant tumors, reaching approximately 30% of all cases. The development of therapies against Ras-dependent tumors has failed despite intense efforts and investments since the discovery in 1982 of its activating mutations in multiple cancers. The objective of this work was to uncover the molecular mechanisms by which FGF2 irreversibly inhibits the proliferation of malignant cells dependent on Ras activity, using as experimental models the Y1 murine lineage of adrenocortical malignant cells and 4 human lineages derived from Ewing sarcomas. We showed that the cytotoxic effect of FGF2 did not involve novel cell cycle regulatory pathways; instead, this cytotoxic effect is a result of sustainedhyper mitogenic stimulation by FGF2. Activation of the KRas/MAPK pathway, the major intracellular mitogenic signaling, at high and sustained levels provokes mitogenic stress, which is propagated to S phase as replicative stress. In this situation, the cell dependence on the ATR protective signaling is enhanced, so that the combination of stimulation with FGF2 and inhibition of ATR was highly lethal for the Ras dependent malignant cells employed in this work. We also analyzed the molecular basis of FGF2 resistance exhibited by Y1 cells previously selected for resistance to FGF2. We found that the selective pressure of FGF2 had no effect on the expression of its receptors but promoted the elimination of one of the two marker chromosomes that carry the K-ras amplified copies, while the second chromosome was maintained because it is the only source of active ribosomal genes; however, its K-ras amplified copies were transcriptionally silenced. In addition, the Y1FRs sublines did not express the main RasGEF, GRP4, found in the parental Y1 cells, which might have played a role in the emergence of the FGF2-resistant phenotype. The resistant Y1FRs sublines showed a large reduction in chromosome numbers and increased frequency of fusions between non-homologous chromosomes in relation to parental cells.

ATR

Estresse replicativo

FGF2

MAPK

Ras

ATR

FGF2

MAPK

Ras

Replicative stress

The NDR1 Kinase, a New Player in Oncogenic Signalling of Ral GTPases, Functions as a Linchpin Between Cancer Cell Survival and Death / La kinase NDR1, un nouvel acteur de la signalisation des RalGTases, fonctionne comme pivot entre la survie et la mort des cellules cancéreuses

Bettoun, Audrey

29 September 2015

Des mutations du gène Ras jouent un rôle essentiel dans le développement tumoral. Les GTPases Ral , RalA et RalB, sont des effecteurs proximaux de l’oncogène Ras. RalA permet la croissance en absence de substrat et RalB est nécessaire à l'autophagie et à la résistance à l'apoptose des cellules cancéreuses. Cette thèse a pour objectif de clarifier les mécanismes moléculaires de la signalisation Ral impliqués dans l’oncogenèse dépendante des protéines Ras.Des criblages par double hydride ont été effectués par notre équipe et un interactome de Ral a été établi. Ce criblage a montré une interaction entre des protéines de la signalisation Ral et la protéine NDR1, une kinase pro-apoptotique appartenant à la voie " suppresseur de tumeur" Hippo. Le Projet 1 montre la régulation de NDR1 par la voie RalA-Exocyste- MAP4K4 en réponse au stress osmotique, oxydatif ou au traitement par le TNF-α. Dans cette voie, la kinase MAP4K4, un effecteur de RalA, via le complexe exocyste active directement NDR1. En outre, nous avons montré que la voie RalA-MAP4K4-NDR1 était nécessaire à l'apoptose déclenchée par le TNF-α ou par la surexpression de RASSF1A, suppresseur de tumeur appartenant à la voie Hippo. Nous avons donc montré que RalA a un rôle pro-apoptotique inattendue qui agit via la kinase NDR1, en plus de son rôle connu de proto-oncogène en aval de Ras.Le projet 2 montre que la protéine kinase NDR1 est un régulateur de l'autophagie. Des criblages par double hydride ont été effectués par notre équipe avec NDR1 comme appât et ont permis de montrer une interaction entre Beclin 1, une protéine majeure de l’autophagie, et NDR1. Nous avons montré que NDR1 était nécessaire à l'autophagie et à la formation des autophagosomes chez l'humain et la Drosophile. De plus, NDR1 est nécessaire à la formation du complexe Exo84 de l'exocyste, Beclin1 et RalB nécessaire à l'initiation de l'autophagie. Nous montrons également que RalB régule l'état d'activation de NDR 1 après induction de l'autophagie. En effet, en absence de RalB, nous avons observé une hyper - activation de NDR1 menant les cellules vers l'apoptose. Ainsi nous avons montré que NDR1 joue le rôle d'interrupteur favorisant l'autophagie ou favorisant l'apoptose suivant son état d'activation.Le projet 3 étudie l'implication de la voie RalGTPases-NDR1 dans l'oncogenèse dépendante de Ras et dissèque par quels mécanismes NDR1 y contribue. / Constitutive Ras signalling is one of the most frequent oncogenic event in human cancers. Thus, it is imperative to identify new therapeutic options targeting downstream effectors of Ras signalling. Ras-like GTPases RalA and RalB are proximal effectors of oncogenic Ras. RalA was reported to support anchorage independent proliferation and RalB regulates autophagy and inhibits apoptosis of cancer cells. Ral proteins execute these functions via several direct effectors as the exocyst, an octameric complex originally identified as regulator of vesicles trafficking. The global goal of this PhD was to better decipher the molecular mechanisms underlying the functions of Ral GTPases in oncogenesis.To extend the Ral interactome, i.e. the protein-protein interaction network centered on Ral, we performed yeast-two hybrid screenings which led to the identification of the NDR1 kinase, belonging to the tumor suppressor Hippo pathway. NDR1 functions in oncogenesis were investigated in the context of three projects.In Project 1, we showed that NDR1-dependent apoptosis is regulated by a RalA/Exocyst/MAP4K4/NDR1 cascade. We reported that under osmotic or oxidative stresses or TNF-α treatment, the Ste20-like MAP4K4 kinase, an effector of RalA via the exocyst complex, directly activates NDR1. Moreover, we found that TNF-α treatment or overexpression of the tumor suppressor RASSF1A, which belongs to the Hippo pathway, leads to apoptosis through this RalA/Exocyst/MAP4K4/NDR1 pathway. This novel and unexpected pro-apoptotic role of RalA suggests that the RalA GTPase can positively signal in tumor suppressor pathways via the kinase NDR1, in addition to its proto-oncogenic role downstream of Ras. In Project 2, we described the NDR1 protein kinase as a conserved regulator of autophagy. Using NDR1 as bait in yeast two hybrid screens, we fished Beclin1, a key regulator of autophagy, and we validated the existence of a direct biochemical NDR1-Beclin1 interaction. We showed that NDR1promotes autophagosome formation in human cells and Drosophila larvae. Furthermore, we observed that NDR1 supports the interaction of the exocyst component Exo84 with Beclin1 and RalB, which is required to initiate autophagosome formation. Very interestingly, under prolonged autophagy, RalB depletion triggers hyperactivation of NDR1 resulting in NDR1-dependent apoptosis. Thus, it appears that the NDR1 kinase could act as a switch between autophagy (=survival) or apoptosis (=death), under the control of RalB. In Project 3, we addressed the role of the newly identified RalGTPases-NDR1axis in Ras - induced oncogenesis and tumorigenesis.

Oncogenèse

Ras

Ral

NDR

Autophagie

Apoptose

Oncogenesis

Ras

Ral

NDR

Autophagy

Apoptosis

La dualité fonctionnelle de la protéine MyD88, dans la signalisation Ras/MAPKs et l'inflammation, conduit à la transformation cellulaire / Dual function of MyD88 in Ras signaling and inflammation, leading to cell transformation

Le Corf, Katy

11 July 2011

MyD88 est une protéine adaptatrice du système immunitaire inné, impliquée dans la défense de l’organisme contre les agents microbiens. Elle est recrutée aux « Toll-like receptors » (TLRs) suite à la reconnaissance par ces derniers de motifs microbiens conservés, les PAMPs (Pathogens-associated molecular patterns). La voie de signalisation ainsi déclenchée va aboutir à la production de cytokines pro-inflammatoires, de chimiokines et d’espèces actives de l’oxygène. De cette façon, les TLRs, via MyD88, constituent la première ligne de défense contre les pathogènes.De nombreuses études ont permis de démontrer que MyD88 est nécessaire pour la réponse inflammatoire, qui promeut la carcinogenèse. Dans le cadre d’une étude sur les TLRs et le cancer, l’équipe a démontré, grâce à une étude in vivo, que MyD88 participe au processus de tumorigenèse médiée par l’oncogène ras et est nécessaire à l’activation de la voie canonique des MAPKs, ainsi qu’à la transformation cellulaire in vitro. Nous avons ensuite déterminé le mécanisme par lequel MyD88 intervient dans la voie de signalisation Ras/MAPKs, en permettant le maintien de l’activation de cette voie. En effet, MyD88 interagit avec une MAPK clé de cette voie : la kinase ERK, et protège cette dernière de sa déphosphorylation par sa phosphatase spécifique MKP-3, MyD88 et MKP-3 se liant à ERK par le même domaine. Nous avons démontré la pertinence de ce mécanisme, grâce à la mise en évidence d’une surexpression de la protéine MyD88 et de son interaction avec la forme phosphorylée d’ERK dans des coupes de tissus tumoraux humains (estomac, poumon, colon).L’ensemble des résultats obtenus au cours de ma thèse ont permis de montrer qu’en plus de son rôle bien défini en tant qu’adaptateur des récepteurs de l’immunité innée dans les processus inflammatoires, MyD88 joue un rôle direct, qui semble être crucial dans la signalisation Ras, le contrôle du cycle cellulaire et la transformation cellulaire / MyD88 is an adaptator protein of the innate immune system, implicated in the défense against microbes. MyD88 is recruited by the Toll-Like Receptors (TLRs) upon there interaction with conserved microbial patterns (PAMPs). Therefore, TLR signaling pathway induces the production of pro-inflammatory cytokines, chemokines and reactive oxygen species. TLRs, via MyD88, form the first line of defense against pathogens. Accumulating evidence points to inflammation as a promoter of carcinogenesis. MyD88 is an adaptor molecule in TLR and IL-1R signaling that was recently implicated in tumorigenesis through proinflammatory mechanisms. Here we have shown that MyD88 is also required in a cell-autonomous fashion for Ras-mediated carcinogenesis in mice in vivo and for MAPK activation and transformation in vitro. Mechanistically, MyD88 bound to the key MAPK, ERK, and prevented its inactivation by its phosphatase, MKP3, thereby amplifying the activation of the canonical Ras pathway. The relevance of this mechanism to human neoplasia was suggested by the finding that MyD88 was overexpressed and interacted with activated ERK in primary human cancer tissues. Collectively, these results show that in addition to its role in inflammation, MyD88 plays what we believe to be a crucial direct role in Ras signaling, cell-cycle control, and cell transformation

MyD88

TLRs

Ras

ERK

Inflammation

Cancer

MyD88

TLRs

Ras

ERK

Inflammation

Cancer

614.5999