Ruthenacarborane and Quinoline: A Promising Combination for the Treatment of Brain Tumors

Draˇca, Dijana, Markovi´c, Milan, Gozzi, Marta, Mijatovi´c, Sanja, Maksimovi´c-Ivani´c, Danijela, Hey-Hawkins, Evamarie

05 May 2023

Gliomas and glioblastomas are very aggressive forms of brain tumors, prone to the development of a multitude of resistance mechanisms to therapeutic treatments, including cytoprotective autophagy. In this work, we investigated the role and mechanism of action of the combination of a ruthenacarborane derivative with 8-hydroxyquinoline (8-HQ), linked via an ester bond (complex 2), in rat astrocytoma C6 and human glioma U251 cells, in comparison with the two compounds alone, i.e., the free carboxylic acid (complex 1) and 8-HQ, and their non-covalent combination ([1 + 8-HQ], in 1:1 molar ratio). We found that only complex 2 was able to significantly affect cellular viability in glioma U251 cells (IC50 11.4 μM) via inhibition of the autophagic machinery, most likely acting at the early stages of the autophagic cascade. Contrary to 8-HQ alone, complex 2 was also able to impair cellular viability under conditions of glucose deprivation. We thus suggest different mechanisms of action of ruthenacarborane complex 2 than purely organic quinoline-based drugs, making complex 2 a very attractive candidate for evading the known resistances of brain tumors to chloroquine-based therapies.

info:eu-repo/classification/ddc/540

ddc:540

Oxygen Glucose Deprivation and Hyperthermia Induce Cellular Damage in Neural Precursor Cells and Immature Neurons

Luca, Luminita Eugenia

18 December 2008

Hyperthermia damages both developing and adult brains, especially when it occurs after ischemia or stroke. Work presented in this dissertation used in vitro models of these stresses to investigate mechanisms underlying damage to immature neurons and neural precursors cultured from embryonic rat brain. Studies described in Chapter 2 investigated the effects of a brief, intense hyperthermic stress (30-45 min at 43ºC). This stress produced a selective depletion of nestin-immunoreactive neural precursor cells, and reduced proliferation, as evidenced by reduced BrdU incorporation into young Tuj1-immunoreactive neurons. The stress activated caspase 3, and produced multiple signs of nuclear damage as well as early and persisting mitochondrial depolarization. Cycloheximide, an inhibitor of protein synthesis, reduced cell death. All these findings suggest an apoptotic death process. Studies described in Chapter 3 used a combination of oxygen-glucose deprivation (OGD, 2 h) followed by mild 41ºC hyperthermia for 90 min (T). The combined OGDT stress reduced both survival in monolayer cultures and colony-forming ability in neurospheres. Cell death occurred gradually over 2 days, and was accompanied by caspase activation that began within 6 h post-stress. Post-stress application of cycloheximide or a general caspase inhibitor (especially qVD-OPH) reduced cell death, but specific inhibitors of caspases 2, 3, 8 or 9 were ineffective. OGDT led to upregulation of the pro-apoptotic protein Bim as well as redistribution of Bax from cytoplasm to mitochondria within 6 h. Persisting mitochondrial depolarization began within 3 h following the combined OGDT stress, but not following individual OGD or T stresses alone. These findings suggest that OGD sensitizes neural precursor cells to hyperthermia-induced damage, and that the combined OGDT stress kills neural precursors via apoptotic mechanisms that include activation of mitochondrial death pathways. Results of these studies suggest that immature neurons and neural precursors are especially vulnerable to hyperthermia-induced damage via apoptotic mechanisms. Pan-caspase inhibitors may be a promising therapeutic strategy to preserve viability of these cells following stroke with hyperthermia.

Effect of human equilibrative nucleoside transporter 1 (hENT1) and ecto-5' nucleotidase (eN) in adenosine formation by neurons and astrocytes under ischemic conditions.

Chu, Stephanie S.T.Y.

17 August 2012

Adenosine (ADO) is an endogenous neuroprotectant. Under ischemic conditions ADO levels rise in the brain up to 100-fold. ADO in the brain is dependent on the movement across cell membranes by equilibrative nucleoside transporters (ENT) or produced from membrane bound ecto-5’ nucleotidase (eN). We used transgenic neurons with neuronal specific expression of human ENT1 (hENT1) and eN knockout (CD73 KO) astrocytes. The aim of this research was to determine the role of ENT1 and eN in ADO release from ischemic-like conditions in primary cultured neurons, astrocytes or co-cultures. Neurons primarily release intracellular ADO via ENTs; this effect was blocked by transporter inhibitor, dipyridamole (DPR). Astrocytes primarily convert ADO extracellularly from eN; this effect was with eN inhibitor α, β-methylene ADP (AOPCP). Combined neuron and KO astrocytes produced less ADO, extracellular ADO was inhibited by DPR but not AOPCP. Overall these results suggest that eN is prominent in the formation of ADO but other enzymes or pathways contribute to rising ADO levels in ischemic conditions.

Adenosine

ecto 5' nucleotidase (CD73)

cerebral ischemia

NMDA

neuron

astrocyte

cell culture

oxygen-glucose deprivation

Effect of human equilibrative nucleoside transporter 1 (hENT1) and ecto-5' nucleotidase (eN) in adenosine formation by neurons and astrocytes under ischemic conditions.

Chu, Stephanie S.T.Y.

17 August 2012

Adenosine (ADO) is an endogenous neuroprotectant. Under ischemic conditions ADO levels rise in the brain up to 100-fold. ADO in the brain is dependent on the movement across cell membranes by equilibrative nucleoside transporters (ENT) or produced from membrane bound ecto-5’ nucleotidase (eN). We used transgenic neurons with neuronal specific expression of human ENT1 (hENT1) and eN knockout (CD73 KO) astrocytes. The aim of this research was to determine the role of ENT1 and eN in ADO release from ischemic-like conditions in primary cultured neurons, astrocytes or co-cultures. Neurons primarily release intracellular ADO via ENTs; this effect was blocked by transporter inhibitor, dipyridamole (DPR). Astrocytes primarily convert ADO extracellularly from eN; this effect was with eN inhibitor α, β-methylene ADP (AOPCP). Combined neuron and KO astrocytes produced less ADO, extracellular ADO was inhibited by DPR but not AOPCP. Overall these results suggest that eN is prominent in the formation of ADO but other enzymes or pathways contribute to rising ADO levels in ischemic conditions.

Adenosine

ecto 5' nucleotidase (CD73)

cerebral ischemia

NMDA

neuron

astrocyte

cell culture

oxygen-glucose deprivation

Régulation du métabolisme énergétique : étude du remodelage bioénergétique du cancer / Regulation of energy metabolism : study of Bioenergetics remodeling in cancer

Obre, Emilie

12 December 2014

Cette thèse étudie le remodelage métabolique des cellules cancéreuses. Trois modèles sont analysés par de nombreuses approches biochimiques et génétiques : (i) des cellules de poumon transduites avec une forme oncogénique de HRASG12V, (ii) des cellules HeLa soumises à une privation de glucose et (iii) des pièces chirurgicales de cancer du poumon. Sur chaque modèle, le remodelage métabolique observé met en jeu de nombreuses voies du catabolisme et de l’anabolisme, notamment la glutaminolyse et la biosynthèse de sérine. Ce travail révèle un rôle important des mitochondries dans ce remodelage, à la fois pour l’apport d’énergie et pour la synthèse d’antioxydants et d’acides aminés, mais aussi de phospholipides. J’ai montré l’impact étendu d’une simple mutation HRASG12V sur un très grand nombre de processus, révélant ainsi l’importance de la génétique dans le remodelage métabolique des cellules cancéreuses. Toutefois, la privation de glucose induit elle aussi un remarquable remodelage à de très nombreux niveaux, depuis l’épissage des ARN messagers jusqu’à la synthèse de sérine. Enfin, cette thèse identifie deux classes bioénergétiques de tumeurs du poumon, ouvrant de nombreuses perspectives pour le diagnostic et la compréhension de ce type de tumeurs, mais aussi pour proposer des stratégies thérapeutiques adaptées. Les résultats identifient des biomarqueurs et des cibles validées sur nos modèles in vitro. Les perspectives de cette thèse vont consister à la transposition de ces approches à la clinique. / This thesis investigates the metabolic remodeling of cancer cells. Three models are analyzed by different biochemical and genetic approaches: (i) lung cells transduced with oncogenic HRASG12V, (ii) HeLa cells challenged with glucose deprivation and (iii) surgical pieces of lung tumors. On each model the observed metabolic remodeling involves numerous catabolic and anabolic pathways, including glutaminolysis and serine biosynthesis. Our work revealed an important role of mitochondria in metabolic remodeling, both for the supply of energy and for the synthesis of antioxidants and amino acids, but also phospholipids. We show the extent of a single mutation HRASG12V on a very large number of metabolic processes, revealing the importance of genetics in the metabolic remodeling of cancer cells. However, glucose deprivation also induced a remarkable remodeling at many levels of cell metabolism, from the splicing of messenger RNAs to serine biosynthesis. In the third part, this thesis identified two bioenergetic classes of lung tumors, opening interesting opportunities for the diagnosis and understanding of this type of tumor, but also to propose appropriate therapeutic strategies. The results identify biomarkers and targets validated in our in vitro models. The outlook of this thesis will be to the implementation of these approaches in the clinic

Métabolisme énergétique

Remodelage métabolique

Mitochondrie

Métabolisme de la sérine

Glucose déprivation

Energy metabolism

Bioenergetics remodeling

Mitochondria

Serine metabolism

Glucose deprivation

Determining the Effects of Pab1 Acetylation at K131 on Stress Granule Dynamics in Saccharomyces cerevisiae

Sivananthan, Sangavi

08 November 2021

Under environmental stress, such as glucose deprivation, cells form stress granules - the accumulation of cytoplasmic aggregates of repressed translational initiation complexes, proteins, and stalled mRNAs. Recent research implicates stress granules in various diseases, such as neurodegenerative disease, but the exact regulators responsible for the assembly and disassembly of stress granules are unknown. Studies detect post-translational modifications on core stress granule proteins. One modification is lysine acetylation, in which a substrate is regulated by a lysine acetyltransferase (KAT) and lysine deacetylase (KDAC). My project deciphers the impact of lysine acetylation on an essential protein found in stress granules, poly(A) binding protein (Pab1) in Saccharomyces cerevisiae. In this work, I demonstrated that acetylation mimic of Pab1-K131 reduces stress granule formation upon glucose deprivation, and other stressors such as ethanol, raffinose, and vanillin. A potential KDAC that might be facilitating this role is Rpd3. Further, electromobility shift assay studies suggest that acetylation mimic of Pab1-K131 negatively impacts poly(A) RNA binding. This work will be useful when exploring therapeutic options when combating diseases linked to stress granules.

Pab1

Stress Granules

Glucose deprivation

Saccharomyces cerevisiae

Lysine acetylation

mRNA

KAT

KDAC

eIF4G1

Pab1-K131

Pab1-K131R

Pab1-K131Q

Preventing Oxygen-Glucose Deprivation Induced Neuronal Death

Malacos, Kristen K.

17 April 2012

No description available.

Biochemistry

Neurobiology

Neurology

Neurosciences

Pharmaceuticals

Pharmacology

ROS

mitoNEET

oxygen-glucose deprivation

reperfusion injury

VGCC blockers

neurodegeneration

stroke and ischemia

Avaliação de parâmetros neuroquímicos em fatias de hipocampo de rato submetidas à privação de oxigênio e glicose

Hansel, Gisele

January 2009

Mesmo a isquemia sendo a terceira causa de morte em países industrializados, os mecanismos relacionados a esta doença ainda continuam polêmicos e obscuros. Utilizou-se a técnica de privação de oxigênio e glicose (OGD) em fatias do hipocampo de rato para investigar parâmetros mitocondriais, neurais, astrogliais e metabólicos no período de isquemia e durante o período de reoxigenação. Os resultados mostraram uma diminuição na atividade mitocondrial durante o período isquêmico que foi mantido durante todo o período de reoxigenação. Analisando o sobrenadante destas fatias submetidas à OGD, foi observado que os níveis de LDH, NSE e GFAP se elevaram. Com relação aos níveis de lactato, verificou-se sua diminuição durante todos os períodos. Os níveis de S100B estavam elevados somente durante o período de reoxigenação. Este aumento pode ser tanto um mecanismo de neuroproteção desta proteína frente ao insulto ou ainda uma liberação por dano celular astrocitário. Além disso, foi observado um grande aumento nos níveis de glutamato durante a isquemia e este aumento retornou no período de reoxigenação. Por fim, houve uma diminuição na captação de glutamato somente no período de reoxigenação. Todos estes resultados podem ser conseqüência de uma hiper-estimulação dos receptores glutamatérgicos devido ao insulto isquêmico. Em resumo, nosso estudo mostrou alterações em diversos parâmetros neuroquímicos específicos tanto no período isquêmico quanto na reoxigenação, mostrando que cada tipo celular, reage diferentemente frente ao insulto isquêmico na técnica de OGD in vitro. / Stroke is the third cause of mortality in industrialized countries, and the mechanisms related to this disease are polemic and unclear. Oxygen and glucose deprivation (OGD) in acute rat hippocampal slices was performed to investigate mitochondrial, neural, astroglial and metabolic neurochemical parameters at different ischemic and reoxygenation periods. Results showed the mitochondrial activity decrease due energy failure during ischemic insult and reoxygenation time. In the supernatant medium, LDH, NSE and glutamate levels were increased and the lactate decrease by the lack of energy observed in the ischemic period. Parameters such as GFAP, S100B and glutamate uptake suffered alterations only at the reoxygenation period. These results have shown the vulnerability of neurons facing ischemic insult. Meanwhile, it was also observed a delayed injure of astrocytes only at reoxygenation time, which demonstrate the difference between cell types at OGD. In summary, our finding has shown altered at specific neurochemical parameters in OGD in vitro which features the ischemic episodes and reoxygenation periods.

Glutamato

Fosfopiruvato hidratase

Isquemia

Proteína glial fibrilar ácida

Proteínas S100

Glutamate uptake

Glial fibrillary acid protein (GFAP)

Ischemia

Neuron-specific enolase (NSE)

Oxygen and glucose deprivation (OGD)

S100B

Avaliação de parâmetros neuroquímicos em fatias de hipocampo de rato submetidas à privação de oxigênio e glicose

Hansel, Gisele

January 2009

Mesmo a isquemia sendo a terceira causa de morte em países industrializados, os mecanismos relacionados a esta doença ainda continuam polêmicos e obscuros. Utilizou-se a técnica de privação de oxigênio e glicose (OGD) em fatias do hipocampo de rato para investigar parâmetros mitocondriais, neurais, astrogliais e metabólicos no período de isquemia e durante o período de reoxigenação. Os resultados mostraram uma diminuição na atividade mitocondrial durante o período isquêmico que foi mantido durante todo o período de reoxigenação. Analisando o sobrenadante destas fatias submetidas à OGD, foi observado que os níveis de LDH, NSE e GFAP se elevaram. Com relação aos níveis de lactato, verificou-se sua diminuição durante todos os períodos. Os níveis de S100B estavam elevados somente durante o período de reoxigenação. Este aumento pode ser tanto um mecanismo de neuroproteção desta proteína frente ao insulto ou ainda uma liberação por dano celular astrocitário. Além disso, foi observado um grande aumento nos níveis de glutamato durante a isquemia e este aumento retornou no período de reoxigenação. Por fim, houve uma diminuição na captação de glutamato somente no período de reoxigenação. Todos estes resultados podem ser conseqüência de uma hiper-estimulação dos receptores glutamatérgicos devido ao insulto isquêmico. Em resumo, nosso estudo mostrou alterações em diversos parâmetros neuroquímicos específicos tanto no período isquêmico quanto na reoxigenação, mostrando que cada tipo celular, reage diferentemente frente ao insulto isquêmico na técnica de OGD in vitro. / Stroke is the third cause of mortality in industrialized countries, and the mechanisms related to this disease are polemic and unclear. Oxygen and glucose deprivation (OGD) in acute rat hippocampal slices was performed to investigate mitochondrial, neural, astroglial and metabolic neurochemical parameters at different ischemic and reoxygenation periods. Results showed the mitochondrial activity decrease due energy failure during ischemic insult and reoxygenation time. In the supernatant medium, LDH, NSE and glutamate levels were increased and the lactate decrease by the lack of energy observed in the ischemic period. Parameters such as GFAP, S100B and glutamate uptake suffered alterations only at the reoxygenation period. These results have shown the vulnerability of neurons facing ischemic insult. Meanwhile, it was also observed a delayed injure of astrocytes only at reoxygenation time, which demonstrate the difference between cell types at OGD. In summary, our finding has shown altered at specific neurochemical parameters in OGD in vitro which features the ischemic episodes and reoxygenation periods.

Glutamato

Fosfopiruvato hidratase

Isquemia

Proteína glial fibrilar ácida

Proteínas S100

Glutamate uptake

Glial fibrillary acid protein (GFAP)

Ischemia

Neuron-specific enolase (NSE)

Oxygen and glucose deprivation (OGD)

S100B

Avaliação de parâmetros neuroquímicos em fatias de hipocampo de rato submetidas à privação de oxigênio e glicose

Hansel, Gisele

January 2009

Mesmo a isquemia sendo a terceira causa de morte em países industrializados, os mecanismos relacionados a esta doença ainda continuam polêmicos e obscuros. Utilizou-se a técnica de privação de oxigênio e glicose (OGD) em fatias do hipocampo de rato para investigar parâmetros mitocondriais, neurais, astrogliais e metabólicos no período de isquemia e durante o período de reoxigenação. Os resultados mostraram uma diminuição na atividade mitocondrial durante o período isquêmico que foi mantido durante todo o período de reoxigenação. Analisando o sobrenadante destas fatias submetidas à OGD, foi observado que os níveis de LDH, NSE e GFAP se elevaram. Com relação aos níveis de lactato, verificou-se sua diminuição durante todos os períodos. Os níveis de S100B estavam elevados somente durante o período de reoxigenação. Este aumento pode ser tanto um mecanismo de neuroproteção desta proteína frente ao insulto ou ainda uma liberação por dano celular astrocitário. Além disso, foi observado um grande aumento nos níveis de glutamato durante a isquemia e este aumento retornou no período de reoxigenação. Por fim, houve uma diminuição na captação de glutamato somente no período de reoxigenação. Todos estes resultados podem ser conseqüência de uma hiper-estimulação dos receptores glutamatérgicos devido ao insulto isquêmico. Em resumo, nosso estudo mostrou alterações em diversos parâmetros neuroquímicos específicos tanto no período isquêmico quanto na reoxigenação, mostrando que cada tipo celular, reage diferentemente frente ao insulto isquêmico na técnica de OGD in vitro. / Stroke is the third cause of mortality in industrialized countries, and the mechanisms related to this disease are polemic and unclear. Oxygen and glucose deprivation (OGD) in acute rat hippocampal slices was performed to investigate mitochondrial, neural, astroglial and metabolic neurochemical parameters at different ischemic and reoxygenation periods. Results showed the mitochondrial activity decrease due energy failure during ischemic insult and reoxygenation time. In the supernatant medium, LDH, NSE and glutamate levels were increased and the lactate decrease by the lack of energy observed in the ischemic period. Parameters such as GFAP, S100B and glutamate uptake suffered alterations only at the reoxygenation period. These results have shown the vulnerability of neurons facing ischemic insult. Meanwhile, it was also observed a delayed injure of astrocytes only at reoxygenation time, which demonstrate the difference between cell types at OGD. In summary, our finding has shown altered at specific neurochemical parameters in OGD in vitro which features the ischemic episodes and reoxygenation periods.

Glutamato

Fosfopiruvato hidratase

Isquemia

Proteína glial fibrilar ácida

Proteínas S100

Glutamate uptake

Glial fibrillary acid protein (GFAP)

Ischemia

Neuron-specific enolase (NSE)

Oxygen and glucose deprivation (OGD)

S100B