Regulation and function of the Mad/Max/Myc network during neuronal and hematopoietic differentiation

Hultquist, Anne

January 2001

The Mad/Max/Myc transcription factor network takes part in the control of vital cellular functions such as growth, proliferation, differentiation and apoptosis. Dimerization with the protein Max is necessary for the Myc-family of oncoproteins and their antagonists, the Mad-family proteins, to regulate target genes and carry out their intended functions. Myc functions as a positive regulator of proliferation, antagonized by the growth inhibitory Mad-proteins that potentially functions as tumor supprerssors. Deregulated Myc expression is found in a variety of tumors and signals negatively regulating Myc expression and/or activity could therefore be of potential use in treating tumors with deregulated Myc. Our aim was to therefore to investigate possible negative effects on Myc expression and activity by growth inhibitory cytokines and by the Myc antagonists, the Mad-family proteins.Two different cellular model systems of neuronal and hematopoietic origin have been utilized for these studies. Our results show that Mad1 is upregulated during induced neuronal differentiation of SH-SY5Y cells. Further, the growth inhibitory cytokine interferon-g (IFN-g) was shown to cooperate with retinoic acid (RA) and the phorbol ester TPA in inducing growth arrest and differentiation in N-myc amplified neuroblastoma cell lines. In contrast to treatment with either agent alone, the combined treatment of TPA+IFN-g and RA+IFN-g led to upregulation of Mad1 and to downregulation of N-Myc, respectively, thus correlating with the enhanced growth inhibition and differentiation observed after combination treatment. Ectopic expression of an inducible Mad1 in monoblastic U-937 cells led to growth inhibition but did not lead to differentiation or enhancement of differentiation induced by RA, vitamin D3 or TPA. In v-Myc transformed U-937 cells Mad1 expression reestablished the TPA-induced G1 cell cycle arrest, but did not restore differentiation, blocked by v-Myc. The growth inhibitory cytokine TGF-b was found to induce Mad1 expression and Mad1:Max complex formation in v-Myc transformed U-937 cells correlating with reduced Myc activity and G1 arrest. In conclusion, our results show that the Myc-antagonist Mad1 is upregulated by growth inhibitory cytokines and/or differentiation signals in neuronal and hematopoietic cells and that enforced Mad1 expression in hematopoietic cells results in growth inhibition and increased sensitivity to anti-proliferative cytokines. Mad1 and cytokine-induced signals therefore seem to cooperate in counteracting Myc activity.

Genetics

Myc

Mad1

neuroblastoma

hematopoiesis

phorbol ester

retinoic acid

interferon-g

TGF-b

differentiation.

Genetik

Clinical genetics

Klinisk genetik

Exploiting Drosophila as a model system for studying anaplastic lymphoma kinase in vivo

Eriksson, Therese

January 2010

Anaplastic Lymphoma Kinase (ALK) is a Receptor Tyrosine Kinase (RTK) and an oncogene associated with several human diseases, but its normal function in humans and other vertebrates is unclear. Drosophila melanogaster has an ALK homolog, demonstrating that the RTK has been conserved throughout evolution. This makes Drosophila a suitable model organism for studying not only Drosophila ALK function, but also to study mammalian forms of ALK. In Drosophila the ligand Jeb activates ALK, initiating signaling crucial for visceral mesoderm development. The activating ligand for mammalian ALK is unclear, and for this reason Drosophila was employed in a cross-species approach to investigate whether Drosophila Jeb can activate mouse ALK. Jeb is unable to activate mouse ALK, and therefore mouse ALK is unable to substitute for and rescue the Drosophila ALK mutant phenotype. This suggests that there has been significant evolution in the ALK-ligand relationship between the mouse and Drosophila. In humans ALK has recently been shown to be involved in the development of neuroblastoma, a cancer tumor in children. I have developed a Drosophila model for examining human gain of function ALK mutants found in neuroblastoma patients. The various ALK variants have acquired point mutations in the kinase domain that have been predicted to activate the RTK in a constitutive and ligand independent manner. When expressed in the fly eye, active human ALK mutants result in a rough eye phenotype, while inactive wild type ALK does not, due to the lack of an activating ligand in the fly. In this way  several of the ALK mutations identified in neuroblastoma patients could be confirmed to be activated in a ligand independent manner. Moreover, a novel ALK mutant; ALKF1174S, was discovered in a neuroblastoma patient and was in the Drosophila model shown to be a gain of function mutation, and a previously predicted gain of function mutation; ALKI1250T, was shown to be a kinase dead mutation. This fly model can also be used for testing ALK selective inhibitors, for identifying activating ligands for human ALK and for identifying conserved components of the ALK signaling pathway. Gut musculature development in Drosophila is dependent on ALK signaling, while somatic muscle development is not. Proteins of the Wasp-Scar signaling network regulate Arp2/3-complex mediated actin polymerization, and I have investigated their function in visceral and somatic muscle fusion. I found that Verprolin and other members of this protein family are essential for somatic but not visceral muscle development. Despite fusion defects in both tissues in Verprolin and other examined mutants, gut development proceeds, suggesting that fusion is not crucial for visceral mesoderm development. Hence the actin polymerization machinery functions in both somatic and visceral muscle fusion, but this process only appears to be essential in somatic muscle development. / Exploiting Drosophila as a model system for studying Anaplastic Lymphoma Kinase in vivo

Anaplastic lymphoma kinase

Receptor tyrosine kinase

Jeb

neuroblastoma

actin polymerization

Wasp

Scar

Vrp1

Arp2/3

Molecular biology

Molekylärbiologi

Analyse génotypique des cellules initiatrices de tumeurs exprimant CD133 dans le neuroblastome

Cournoyer, Sonia

03 1900

Le neuroblastome (NB) est la tumeur solide extracranienne la plus fréquente et mortelle chez les jeunes enfants. Il se caractérise par une résistance à la chimiothérapie possiblement en partie dû à la présence de cellules initiatrices de tumeurs (TICs). Des études ont mis en évidence le rôle de CD133 comme un marqueur des TICs dans divers types de cancers. Les buts de notre travail étaient d’abord de démontrer les vertus de TICs des cellules exprimant CD133 et ensuite, en utilisant une analyse globale du génome avec des polymorphismes nucléotidiques simples (SNPs), d’effectuer une analyse différentielle entre les TICs et les autres cellules du NB afin d’en identifier les anomalies génétiques spécifiques. Des lignées cellulaires de NB ont été triées par cytométrie de flux afin d’obtenir deux populations: une enrichie en CD133 (CD133high), l’autre faible en CD133 (CD133low). Afin de déterminer si ces populations cellulaires présentent des propriétés de TICs, des essais sur les neurosphères, les colonies en agar mou et les injections orthotopiques de 500 cellules sélectionnées dans 11 souris ont été réalisées. Après une isolation de l’ADN des populations sélectionnées, nous avons effectué une analyse génotypique par SNP utilisant les puces « Affymetrix Genome-Wide Human SNP Array 6.0 ». Pour vérifier l’expression des gènes identifiés, des Western Blots ont été réalisés. Nos résultats ont démontré que la population CD133 avait des propriétés de TICs in vitro et in vivo. L’analyse génotypique différentielle a permis d’identifier deux régions communes (16p13.3 and 19p13.3) dans la population CD133high ayant des gains et deux autres régions (16q12.1 and 21q21.3) dans la population CD133low possédant des pertes d’hétérozygoties (LOH). Aucune perte n’a été observée. Parmi les gènes étudiés, l’expression protéique d’éphrine-A2 était corrélée à celle de CD133 dans 6 tumeurs et 2 lignées cellulaires de NB. De plus, l’augmentation de la concentration d’anticorps anti-éphrine-A2 dans le milieu diminue la taille des neurosphères. Ainsi, la population CD133high, qui a des vertus de TICs, possède des caractéristiques génotypiques différentes par rapport à celle CD133low. La présence d’éphrine-A2 dans les cellules exprimant CD133 souligne son importance dans le développement des TICs. Ces résultats suggèrent la présence de potentielle cible pour de nouvelles thérapeutiques ciblant les TICs mise en évidence par l’étude génomique. / Neuroblastoma (NB) is the most common and deadly extracranial solid tumor of childhood characterized by a resistance to chemotherapy possibly due to the presence of tumor initiating cells (TICs). Studies showed the role of CD133 as a marker of TICs in various types of cancers. Our goals were first to demonstrate the stemness of TICs expressing CD133 and then, using a global genomic analysis with single nucleotide polymorphism (SNPs), to perform a differential analysis between TICs and other cells of NB to identify the specific genetic abnormalities. NB cell lines were sorted by flow cytometry to obtain two populations: one enriched in CD133 (CD133high), the other low in CD133 (CD133low). To determine whether these cell populations have TICs properties, we test the ability of cells to form either neurosphères or, colonies in soft agar and we also test their carcinogenic properties by orthotopic injections of 500 selected cells in 11 mice. After a DNA extraction on selected populations, a differential genotyping analysis has been made with Affymetrix Genome-Wide Human SNP Array 6.0. To verify the expression of the genes identified, Western blots had been made. Our results have demonstrated that CD133high population presented TICs properties in vitro and in vivo. The differential genotyping analysis allowed identifying two gains common regions (16p13.3 and 19p13.3) in CD133high population and two others loss of heterozygosity (LOH) (16q12.1 and 21q21.3) in CD133low population . No losses were observed. Among the genes studied, ephrin-A2 protein expression was correlated to CD133 expression in 6 NB tumors and 2 NB cell lines. Also, ephrin-A2’s increased concentration influenced the neurospheres by decreasing their size. Thereby, CD133high population, which had TICs properties, possess different genotyping characteristics compared to CD133low population. The presence of ephrine-A2 in cells expressing CD133 emphasizes its importance in the development of TICs. These results suggest the presence of potential target for new therapies targeting the TICs demonstrated by the genomic study.

Neuroblastome

Cellules initiatrices de tumeurs

Analyse génotypique

CD133

SNP

Neuroblastoma

Tumor initiating cells

Genotyping analysis

Étude préclinique de nouveaux médicaments inhibiteurs de PARP et Bcl-2 dans le neuroblastome

Addioui, Anissa

02 1900

Le neuroblastome (NB) est la tumeur solide extracranienne la plus fréquente chez le jeune enfant. En dépit de plusieurs avancements thérapeutiques, seulement 60% survivront à long terme. Cette résistance aux traitements est possiblement due, en partie, à la présence des cellules souches cancéreuses (CSC). PARP-1 joue un rôle important dans la chimiorésistance de certaines tumeurs et son inhibition a montré une potentialisation des agents anticancéreux conventionnels. De plus, Bcl-2 est surexprimé dans le NB et son expression accrue contribuerait à la résistance à la chimiothérapie. Le but de notre travail était de déterminer les effets in vitro d’un PARP inhibiteur, AG-014699 (AG), et d’un inhibiteur de Bcl-2, Obatoclax (Obx), in vitro et in vivo, en monothérapie ou en combinaison avec de la Doxorubicine (Doxo) ou du Cisplatin (Cis), deux agents anticancéreux classiquement utilisés dans le traitement du NB. Afin de déterminer l’expression de PARP-1 dans les tumeurs de NB, nous avons analysé une cohorte de 132 tumeurs. Nous avons utilisé le test MTT afin d’évaluer la sensibilité de 6 lignées cellulaires de NB et des CSC à un traitement avec AG seul ou en combinaison avec de la Doxo ou du Cis. Nous avons déterminé l’étendue de la mort cellulaire par Annexin-V et caractérisé les dommages à l’ADN à l’aide d’un marquage γH2aX. De plus, les modulations des voies de signalisation intracellulaire ont été analysées par Western Blot. La sensibilité des cellules à l’Obx a été analysée par MTT sur 6 lignées cellulaires de NB et sa combinaison avec le Cis a également été déterminée dans 2 lignées cellulaires. Le marquage Annexin-V et des combinaisons avec ZVAD-FMK ont aussi été utilisés pour caractériser les effets d’Obx sur l’apoptose. Des expériences in vivo ont également été faites. Nos résultats démontrent que l’expression de PARP-1 est associée aux tumeurs moins agressives. AG n’a peu ou pas effet sur la croissance tumorale et ne potentialise pas significativement les effets de la Doxo ou de Cis. AG combiné à la Doxo semble sensibiliser les CSC dans une lignée cellulaire. L’Annexin-V et le marquage γH2aX ne révèlent pas d’effets synergiques de cette combinaison et les dommages à l’ADN et la mort cellulaire observés sont attribués à la Doxo. Cependant, on observe une augmentation d’apoptose et de bris d’ADN dans une lignée cellulaire (SK-N-FI) lorsqu’AG est utilisé en monothérapie. On observe une surexpression de pAKT et pERK suite à la combinaison Doxo et AG. Les cellules de NB sont sensibles à l’Obx à des concentrations à l’échelle nanomolaire. De plus, Obx active la mort cellulaire par apoptose. Aussi, Obx a un effet synergique avec le Cis in vitro. In vivo, l’Obx diminue significativement la taille tumorale. Nous concluons que l’Obx présente une avenue thérapeutique prometteuse dans le traitement du NB alors que l’utilisation d’AG ne semble pas être aussi encourageante. / Neuroblastoma (NB) is the most common extracranial solid tumour of childhood. In spite of many therapeutic improvements, only 60% survive long term. Presence of cancer stem cell (CSCs) is thought to mediate such resistance. PARP-1 plays an important role in the chemoresistance of certain tumours and its inhibition is shown to potentiate cells to routinely used anticancer agents. Moreover, Bcl-2 is over-expressed in NB and that its increased expression would contribute to chemotherapy resistance. Our goal was to determine the efficacy in vitro of a PARP inhibitor, AG-014699 (AG), and a Bcl-2 inhibitor, Obatoclax (Obx), in vitro and in vivo, in monotherapy or in combination to Doxorubicine (Doxo) and Cisplatine (Cis), classical chemotherapeutic agents used in NB treatment. In order to determine PARP-1 expression in NB tumours, 132 tumours were analyzed. We used an MTT test to evaluate 6 NB cell line and CSC sensitivity to AG alone or in combination to Doxo and Cis. We investigated the extent of cell death by Annexin-V and determined the degree of DNA damage by γH2aX staining. Also, signalling pathway modulations were analyzed by Western Blots. Obx sensitivity was determined by MTT test on 6 NB cell lines and its combination to Cis was also examined in 2 NB cell lines. Annexin-V and combinations to ZVAD-FMK also evaluated its effect on apoptosis. In vivo experiments were also done. Our results show that PARP-1 is associated to less aggressive tumors. AG has little to no effect on tumour growth when used alone and does not potentiate the effects of Doxo and Cis although more experiments will be needed. AG combined to Doxo seems to sensitize CSC in one cell line. Annexin-V and γH2aX staining reveal no effects of AG combination and Doxo mostly confers all cell damage and death. However, we do observe an increase in DNA damage and apoptosis in one cell line (SK-N-FI) when AG is used in monotherapy. pAKT and pERK are upregulated by Doxo and AG combination. NB cells are sensitized to Obx at nanomolar concentrations. Also, Obx activates apoptotic cell death. Moreover, Obx synergizes with Cis in vitro. In vivo, Obx significantly decreases tumor size. We conclude that Obx seems like a promising therapeutic approach in NB treatment whilst AG does not look so encouraging.

Neuroblastome

Cellules souches cancéreuses

AG-014699

Obatoclax

Neuroblastoma

Cancer stem cells

Localisation of protein kinase C in apoptosis and neurite outgrowth

Schultz, Anna.

January 2005

Thesis (Ph. D.)--Lunds universitet, 2005. / Title from title screen. Description based on contents viewed May 20, 2005. Includes bibliographical references (p. [36]-[48]).

Investigation of inhibitors of polysialyltransferase as novel therapeutics for neuroblastoma : development of in vitro assays to assess the functionality and selectivity of novel small-molecule inhibitors of polysialyltransferases for use in neuroblastoma therapy

Saeed, Rida Fatima

January 2015

Polysialic acid is a unique carbohydrate that decorates the surface of the neural cell adhesion molecule. Polysialic acid is an onco-developmental antigen, expressed in tumours principally of neuroendocrine origin, notably neuroblastoma, strongly correlating with invasion and metastasis. Polysialylation is regulated by two polysialyltransferase enzymes, PST (ST8SiaIV) and STX (ST8SiaII), with STX dominant in cancer. Post-development polysialic acid expression is only found at low levels in the brain, thus this could be a novel target for cancer therapy. It is hypothesized that inhibition of polysialyltransferase could lead to control of tumour dissemination and metastasis. The aims of this thesis were to develop tools and in vitro assays to screen novel polysialyltransferase inhibitors. A panel of tumour cell lines were characterised in terms of growth parameters (using the MTT assay) and polysialic acid expression. This includes a pair of isogenic C6 rat glioma cells (C6-STX and C6-WT) and naturally polysialic acid expressing neuroblastoma cells (SH-SY5Y). Following this, an in vitro assay was validated to screen modulation of polysialic acid expression by removing pre-existing polysialic acid expression using endoneuraminidase N and evaluated the amount of re-expression of polysialic acid using immunocytochemistry. Then, a functional assay was developed and validated for invasion, the matrigel invasion assay. Cytidine monophosphate (tool compound) significantly reduced polysialic acid surface expression and invasion. A panel of six novel polysialyltransferase inhibitors was screened for cytotoxicity, polysialic acid surface expression and invasion. Of the potential polysialyltransferase inhibitors evaluated, ICT3176 and ICT3172 were identified from virtual screening of Maybridge library and were emerged as the most promising inhibitors, demonstrating significant (p < 0.05) reduction in cell-surface polysialic acid re-expression and invasion in polysialic acid expressing cells. Furthermore, the specificity of compounds for polysialyltransferase (α-2,8-sialyltransferase) over other members of the wider sialyltransferase family (α-2,3- and α-2,6-sialyltransferases) was confirmed using differential lectin staining. These results demonstrated that small molecule inhibitors as STX is possible and provides suitable in vitro cell based assays to discovery more potent derivatives.

Propriedades antioxidantes, anti-inflamatórias e antinociceptivas do ácido chiquímico

Rabelo, Thallita Kelly

January 2016

A investigação do potencial terapêutico de compostos naturais não tóxicos capazes de prevenir ou reduzir o impacto do estresse oxidativo em doenças inflamatórias diretamente relacionadas a dor tem exercido um papel fundamental no desenvolvimento de novas medicamentos. O ácido chiquímico (ACH) é um composto natural originalmente extraído da Illicium verum Hook. f., uma planta medicinal usada no tratamento de doenças inflamatórias. Apesar do ACH ter sido usado como um precursor químico na síntese do antiviral Tamiflu®, o seu potencial como um composto anti-inflamatório e antioxidante, já enraizado pelo uso popular, ainda permanece desconhecido. Baseado nisso, o objetivo do presente estudo foi avaliar a atividade antioxidante, anti-inflamatória e antinociceptiva do ACH em modelos in vitro e in vivo. Inicialmente as propriedades físico-químicas do ACH foram avaliadas e a atividade antioxidante comprovada, bem como seu potencial de proteger a morte celular induzida por peróxido de hidrogênio em células de neuroblastoma SH-SY5Y. O ACH atenuou a inflamação induzida pelo LPS em macrófagos RAW 264.7, foi capaz de inibir a produção de citocinas (TNF-α e IL-β) e de NO, assim como a ativação das MAPKs (ERK1/2 e P38) induzida pelo LPS, sugerindo que o ACH pode exercer uma atividade anti-inflamatória. In vivo, o ACH bloqueou a hiperalgesia mediada pela carragenina (CG), TNF-α, prostaglandinas (PEG2) e dopamina (DA) em camundongos. Esses resultados sugerem que o efeito antinociceptivo do ACH pode ser atribuído, em parte, a sua ação antioxidante e anti-inflamatória, dois mecanismos que sustentam a transdução do sinal doloroso. / The investigation of the therapeutic potential of natural non-toxic compounds capable of counteracting oxidative stress associated with inflammatory disease and painful conditions, has been of key interest in drug development. Shiquimic acid (SA) is a nature-derived compound originally extracted from Illicium verum Hook. f., a chinese medicinal herb used to treat inflammatory diseases. Even though SA has currently been used as a chemical precursor for synthesis of the antiviral Tamiflu, its potential as an anti-inflammatory and antioxidant compound – already rooted by its popular use - remains unknown until now. Based on that, the aim of this study was to evaluate the antioxidant, anti-inflammatory and anti-nociceptive activity of SA in vitro and in vivo models. Initially the physic-chemical properties of SA were evaluated and proven antioxidant activity, as well as its potential to protect hydrogen peroxide-induced cell death in neuroblastoma SH-SY5Y cells. SA attenuates LPS-induced inflammation in RAW 264.7 macrophages, SA was capable of inhibiting TNF-α and IL-1β cytokines production, NO production as well as LPS-induced activation of MAPKs (p38 and ERK1/2), thus suggesting that SA may exert anti-inflammatory activity. In vivo, SA blocked carrageenan, TNF-alpha-, prostaglandin (PE2)-, and dopamine-induced hyperalgesia in mice. These results suggest that anti-nociceptive effect of SA could be attributed, at least in part, to their antioxidant and anti-inflammatory actions, two mechanisms underpinning painful signal transduction.

Ácido chiquímico

Oxirredução

Inflamação

Dor

Anti-inflamatórios

Antioxidantes

Estresse oxidativo

Neuroblastoma

Shikimic acid

Antioxidants

Inflammation

Nociception

SH-SY5Y

RAW 264.7

Investigating the Effect of 1,25-Dihydroxyvitamin D3 and Retinoic acid on Viability, Differentiation and Migration in NB69 and T47D cells.

Saxenborn, Patricia

January 2016

Cancer is a well-known disease that many people encounter in their lifetime. There is constantly research being performed on cancer to find treatments for those types where none has been found, or even find better or more efficient treatments for those cancer types where there already is treatment available. Two types of cancer that have been studied in this thesis are neuroblastoma, which is a form of cancer that affects children and infants, and breast cancer. The 13-cis retinoic acid is presently used as treatment for neuroblastoma post-surgery and post-chemo therapy, but the treatment is quite invasive. It has been shown that 1,25-dihydroxyvitamin D3 is a good candidate for cancer treatment, and the aim of this study was to investigate whether a combination of 1,25-dihydroxyvitamin D3 and two forms of retinoic acid, all-trans and 13-cis, could cause synergistic effects on cell viability, invasion, and differentiation of the cells. The two vitamins were combined at different concentrations and ratios to make the different treatments. A proliferation assay with absorbance measurement was performed to determine cell viability, and a migration assay was performed to observe the migratory properties of the cells after treatment. The results concluded that the combined treatments had greater effect than the single treatments on cell viability in both neuroblastoma and breast cancer cells. The results showed that single treatment of 13-cis retinoic acid and combined treatments had the highest effect on invasion and differentiation on neuroblastoma cells.

neuroblastoma

breast cancer

retinoic acid

vitamin D

cancer

proliferation

differentiation

migration

Cell Biology

Cellbiologi

Cancer and Oncology

Cancer och onkologi

Caracterização da diferenciação neural induzida por ácido retinóico da linhagem de neuroblastoma humano SH-SY5Y e seu uso como ferramenta para pesquisa em neurociências

Lopes, Fernanda Martins

January 2012

Os mecanismos moleculares que levam ao dano da via nigroestriatal durante a progressão da Doença de Parkinson (DP) ainda não estão totalmente elucidados. Dessa forma, existe a necessidade de desenvolver modelos experimentais adequados para o estudo desse distúrbio neurodegenerativo. A linhagem de neuroblastoma humano SH-SY5Y tratada com neurotoxinas indutoras deste distúrbio (ex.: 6-hidroxidopamina - 6-OHDA) é amplamente utilizada como modelo in vitro da DP. Muitos estudos mostram que esta linhagem pode ser diferenciada em células dopaminérgicas através da combinação da diminuição do soro fetal bovino (SFB) em meio de cultura e da adição de neurotrofinas como o ácido retinóico (AR). No entanto, há poucos estudos mostrando as diferenças entre células proliferativas e diferenciadas da linhagem de neuroblastoma SH-SY5Y, além do efeito do tratamento com 6-OHDA. Ainda, não há um consenso nos protocolos de diferenciação. Dessa forma, o objetivo deste estudo foi estabelecer um protocolo de diferenciação dopaminérgica da linhagem de neuroblastoma humano SH-SY5Y, bem como avaliar a potencialidade do modelo como plataforma para o screening de neurotoxicidade/neuroproteção de compostos e a possibilidade de manipulação gênica. As células proliferativas SH-SY5Y foram mantidas em meio de cultura DMEM/F12 (1:1) suplementado com 10% de SFB. A diferenciação foi induzida pela combinação de 10 μM de AR e meio de cultura com 1% de SFB durante 4, 7 e 10 dias. Foram avaliados parâmetros morfológicos (presença de neuritos) e neuroquímicos, através marcadores de diferenciação neuronal (DAT- transportador de dopamina; TH – tirosina hidroxilase; ENS – enolase neurônio específica; NeuN – proteína nuclear de neurônio; Nestina). Ainda, avaliamos parâmetros de estresse oxidativo através da atividade de enzimas antioxidantes e dos níveis de tióis reduzidos. Nossos dados mostraram que as células SH-SY5Y diferenciadas por 7 dias apresentaram mudanças morfológicas e o aumento do imunoconteúdo de todos os marcadores neuronais testados, e a concomitantemente diminuição do imunoconteúdo de nestina (marcador de células indiferenciadas). Além disso, o fenótipo neuronal apresentou uma maior atividade de alguns sistemas antioxidantes. Também foi avaliada a citotoxicidade frente ao H2O2 e à 6-OHDA nos dois fenótipos. As células diferenciadas se mostraram mais resistentes ao dano causado pelo H2O2 e mais sensíveis à 6-OHDA. Dessa forma, a citotoxicidade da 6-OHDA pode estar relacionada com o aumento do imunoconteúdo do DAT, visto que a neurotoxina entra na célula dopaminérgica através deste transportador. Interessantemente, as células diferenciadas apresentaram aumento dos níveis da proteína neuroprotetora DJ-1, que está relacionada a uma forma prematura de Parkinsonismo em humanos. Após a caracterização do modelo, nós utilizamos o fenótipo diferenciado como plataforma experimental para o screening de compostos neuroprotetores como os organocalcogênios. Nós determinamos a citotoxidade destes compostos em células diferenciadas da linhagem de neuroblastoma SH-SY5Y. A partir destes dados, foram selecionados compostos com baixa citotoxicidade e avaliamos a morfologia celular (densidade de neuritos). Nós verificamos que antes da perda de viabilidade, ocorre a perda de neuritos, sendo que este parâmetro é outra vantagem do modelo de célula diferenciada para avaliação da neurototoxicidade. Ainda, verificamos que estes compostos são capazes de prevenir o dano celular causado pela 6-OHDA. Além disso, nós caracterizamos a capacidade do modelo de ser manipulado geneticamente através da transfecção e superexpressão de plasmídeo contendo a proteína verde fluorescente, onde verificamos que a expressão é mantida durante a diferenciação. Dessa forma, nossos dados mostraram a eficácia da padronização da diferenciação induzida por AR da linhagem de neuroblastoma humano SH-SY5Y, pois estas células apresentam características morfológicas e neuroquímicas adequadas de neurônio dopaminérgico bem como pode ser aplicado não só para avaliação de neurototoxicidade/neuroproteção, mas também pode ser manipulado geneticamente. / The molecular mechanisms underlying the massive cellular loss found in the nigrostriatal pathway during the progression of Parkinson’s disease (PD) are not completely understood. Therefore, it is important to develop more suitable experimental models to study the molecular mechanisms of this neurodegenerative disorder. Proliferative human neuroblastoma cell line SH-SY5Y challenged with neurotoxins (e.g.: 6-hydroxydopamine – 6-OHDA) has been widely used as an in vitro model for PD. Many lines of evidence showed that this cell line differentiates with the combination of lower fetal bovine serum (FBS) and retinoic acid (RA) to dopaminergic-like neural cell. However, there are few studies addressing the differences between proliferative and RA-differentiated SH-SY5Y cells as well as their responses to 6-OHDA cytotoxicity. Moreover, there is no consensus in differentiation protocols. Hence, the objective of this study was to establish a RAinduced dopaminergic differentiation protocol and also evaluate its capabilities for drug screening of neurotoxicity/neuroprotection and genetic manipulation. Exponentially growing SH-SY5Y cells were maintained with DMEM/F12 (1:1) medium plus 10% FBS. Differentiation was triggered by the combination of 10 μM of RA plus medium with 1% of FBS during 4, 7 and 10 days. We evaluated the cell morphology (neurites) and the neuronal markers (Dopamine Transporter- DAT, Tyrosine Hydroxylase-TH, Neuron-Specific Enolase-NSE, Neuronal Nuclei Protein- NeuN, and Nestin immunocontent). Furthermore, we verify the activity of antioxidant enzymes and the reduced thiol levels. Our data demonstrated that SH-SY5Y cells differentiated for 7 days expresses all neuronal markers tested with concomitant decrease in nondifferentiated marker (nestin). Besides, they showed a higher activity of some antioxidant systems. We also evaluated the cytotoxicity of H2O2 and 6-OHDA in both phenotypes. Differentiated cells are more resistant to H2O2 and more sensitive to 6- OHDA. Hence, the damage caused by 6-OHDA could be related with the increase of DAT immuncontent, because this neurotoxin enters into the dopaminergic cell through this transporter. Interestingly, the differentiated cells have more levels of neuroprotective DJ-1 protein, which is related with a juvenile Parkinsonism. After establish the conditions of differentiation, we used the neuronal phenotype to perform a drug screening with organoselenide compounds. We verify the cytotoxicity of these compounds in differentiated cells. From these data, we selected compounds with low toxicity and evaluated the cell morphology (neurites density). We verify that before the loss of viability, there is a loss of neurites. This parameter is another advantage of the differentiated cells model to neurotoxicity evaluation. Moreover, these compounds were able to prevent neuronal cell death caused by 6-OHDA. We also characterized the ability of the model to be manipulated genetically through transfection and overexpression of a green fluorescent protein (GFP) plasmid. We verify that the expression of GFP is maintained during the differentiation. Hence, our data showed the efficacy of the RA-induced differentiation protocol of the neuroblastoma cell line SH-SY5Y, because these cells have morphological and neurochemical characteristics of dopaminergic neurons. Furthermore, the neuronal phenotype can be applyed not only to evaluate neurocytotoxicity/neuroprotection but also can be manipulated genetically.

Doença de Parkinson

Estresse oxidativo

Diferenciação celular

Neuroblastoma

Tretinoína

Parkinson disease

SH-SY5Y

6-hydroxydopamine

Experimental model

Cell differentiation

Oxidative stress

Neuropatia diabética : estudo dos mecanismos moleculares envolvidos com a neurotoxicidade do metilglioxal e do glicolaldeído em células diferenciadas de neuroblastoma humano SH-SY5Y

Londero, Giovana Ferreira

January 2012

Neuropatia é a complicação mais comum e mais debilitante da Diabetes Mellitus, a longo prazo presente em mais de 50% dos pacientes que possuem a doença. A hiperglicemia induz estresse oxidativo nos neurônios de diabéticos acarretando a ativação de múltiplas vias bioquímicas, as quais são potenciais alvos terapêuticos para a neuropatia diabética. Está claro que compostos carbonil reativos são mediadores glicotóxicos do estresse oxidativo através da formação de produtos finais de glicação avançada como resultado direto da hiperglicemia. Metilglioxal e glicolaldeído são compostos carbonil reativos inevitavelmente produzidos pelo metabolismo, os quais são encontrados em maior quantidade em situações de hiperglicemia. Recentemente, tem sido dada muita atenção para o envolvimento de espécies reativas na toxicidade do metilglioxal e do glicolaldeído, e tem-se demonstrado que essas glicotoxinas têm potencial para induzir estresse oxidativo, parar o crescimento celular e promover morte por apoptose ou necrose. O metilglioxal e o glicolaldeído interagem com grupamentos sulfidril de moléculas de glutationa e de enzimas, inibindo sua atividade; entretanto, os mecanismos moleculares relacionados aos efeitos tóxicos dessas glicotoxinas e as vias pelas quais elas levam a formação de espécies reativas não estão completamente elucidados. Neste estudo nós buscamos esclarecer a relação entre o metabolismo do metilglioxal e do glicolaldeído e a produção de espécies reativas, e investigamos as possíveis rotas de morte celular envolvidas. Utilizamos a linhagem celular de neuroblastoma humano SH-SY5Y diferenciada, pois este é um modelo neuronal bem caracterizado para estudos de compostos neurotóxicos. Nós avaliamos a produção de espécies reativas induzida por metilglioxal e glicolaldeído através da técnica da diclorofluoresceína, e avaliamos, também, seus efeitos sob o conteúdo de glutationa celular. Além disso, investigamos a ativação das caspase-3, -8 e -9 e a contribuição de diferentes sistemas peroxidases (glutationa-redutase e a tioredoxina-redutase), na defesa neuronal contra essas glicotoxinas. Como resultados encontramos que o tratamento com ambas glicotoxinas rapidamente provocou um aumento na produção de espécies reativas e diminuição do conteúdo de glutationa, com concomitante ativação das caspases-8 e -9 e, posteriormente, também houve ativação da caspase-3 pelo tratamento com metilglioxal. Vimos que a tioredoxina-redutase possui um papel mais importante na defesa celular contra a toxicidade do metilglioxal do que contra o glicolaldeído, enquanto que a glutationa-redutase tem papel semelhante na defesa celular contra ambas glicotoxinas. Nossos resultados demonstraram que o estresse oxidativo é um importante mecanismo da toxicidade do metilglioxal e do glicolaldeído nas células diferenciadas SHSY5Y e, que enzimas redutoras de grupamentos sulfidril contribuem de diferentes formas na defesa celular contra cada uma dessas glicotoxinas. / Neuropathy is the most common and debilitating complication of Diabetes Mellitus present in more than 50% of the patients with long-standing disease. Hyperglycemia induces oxidative stress in neurons from diabetic patients and results in activation of multiple biochemical pathways. These activated pathways are a major source of damage and are potential therapeutic targets in diabetic neuropathy. A large body of evidence has implicated reactive carbonyl compounds as glycotoxic mediators of oxidative stress by forming advanced glycation endproducts as a direct result of hyperglycemia. Methylglyoxal and glycolaldehyde are reactive carbonil compounds inevitably produced by the metabolism, but they are found in increased rates under hyperglycemia condition. Recently, the attention has been focused on the involvement of reactive species in methylglyoxal and glycolaldehyde toxicities, resulting in oxidative stress and leading to cell growth arrest, apoptotic or necrosis death. These glycotoxins interact with sulfhydryl-groups of glutathione molecules enzymes, inhibiting their activity; however, the molecular mechanism underlying methylglyoxal and glycolaldehyde cytotoxic effects and reactive species generation are not fully understood. In this study we have pursued to establish the role of methylglyoxal and glycolaldehyde metabolisms and reactive species production, and have looked for the possible death routes involved with the toxic effects of these glycotoxins. Here we used the differentiated human neuroblastoma SH-SY5Y cells as neuronal experimental model to investigate the pathological effects of various neurotoxic compounds. We have evaluated the methylglyoxal and glycolaldehyde capacity to reactive species generation by dichlorofluorescein assay and their effects upon cellular glutathione content. Also, we have assessed the caspase-3, -8 and -9 activation and the contribution of different peroxidases systems (glutathione reductase and thioredoxin reductase) in the neuronal defense against methylglyoxal and glycolaldehyde cytotoxicities. We found that both glycotoxins promptly provoke reactive species generation and decrease the cell glutathione content, as well induce caspase-8 and -9 activation. Later caspase-3 activation was found in methylglyoxal treatment. We demonstrate that thioredoxin reductase has a most important role in cell defense against methylglyoxal toxicity than against glycolaldehyde, meanwhile there is no difference in the glutathione reductase role. Our results show that oxidative stress is an important mechanism in the methylglyoxal and glycolaldehyde toxicities and sulfhydryl reductases contributes differently in the cellular defense against these glycotoxins.

Neuropatias diabéticas

Estresse oxidativo

Metilglioxal

Neuroblastoma

Neurotoxicidade

Diabetes neuropathy

Oxidative stress

Methylglyoxal

Glycolaldehyde

Neurotoxicity

SH-SY5Y cells