Vliv psychotropních látek na mitochondriální funkce. / The effect of psychotropic drugs on the mitochondrial functions.

Cikánková, Tereza

January 2020

Psychopharmaca are a large group of drugs widely used not only in psychiatry. Their systemic administration affects both the main diagnosis and the organism as a whole. The subject of our experiments is the effect of psychopharmaca on the changes in mitochondrial functions, which is beneficial for understanding of molecular mechanisms of therapeutic and adverse effects of drugs. The aim of this thesis was to study the in vitro effects of selected drugs on the cell energy metabolism. Selected antipsychotics (chlorpromazine, levomepromazine, haloperidol, risperidone, ziprasidone, zotepine, aripiprazole, clozapine, olanzapine, and quetiapine), antidepressants (bupropion, fluoxetine, amitriptyline, imipramine) and mood stabilizers (lithium, valproate, valpromide, lamotrigine, carbamazepine) were tested. In vitro effects of selected psychopharmaca were measured on isolated pig brain mitochondria. The activities of citrate synthase (CS) and electron transport chain (ETC) complexes (I, II+III, IV) were measured spectrophotometrically. Drug-induced changes of mitochondrial respiration rates linked to complex I (supported by malate and pyruvate) and complex II (supported by succinate) were evaluated by high resolution respirometry. Complex I was significantly inhibited by lithium, carbamazepine, fluoxetine,...

Towards the Regulation and Physiological Role of the Mitochondrial Calcium- Independent Phospholipase A₂

Rauckhorst, Adam J.

January 2014

No description available.

Biochemistry

Biomedical Research

Mitochondria

bioenergetics

electron transport chain

phospholipase A2

Calcium-independent phospholipase A2

mitochondrial dynamics

mitophagy

mitochondrial permeability transition

Metabolic Characterization of MPNST Cell Lines

Waker, Christopher A.

02 June 2015

No description available.

Biomedical Research

Cellular Biology

Neurosciences

Neurofibromatosis Type 1

malignant peripheral nerve sheath tumor

metabolism

glycolysis

oxidative phosphorylation

ROS

mitochondria

proton leak

NF1

Ras

Electron transport chain

Extracellular Flux

Superoxide Dismutase 2 Overexpression Attenuates Effects of Ischemia Reperfusion-Induced Mitochondrial Dysfunction

Lin, Paul P.

03 October 2017

No description available.

Biology

Superoxide

SOD2

MnSOD

Heart

Heart Mitochondria

Mitochondria

Electron transport chain

Antioxidant

Ischemia Reperfusion

IR

Krebs Cycle

Catalase

Glutathione Peroxidas

Oxidative Stress

Regulation of mitochondrial ATPase by its inhibitor protein IF1 in Saccharomyces cerevisiae / Régulation de l’ATP synthase mitochondriale par son inhibiteur endogène IF1 chez Saccharomyces cerevisiae

Wu, Qian

12 December 2013

ATP synthase est une protéine essentielle associée à la membrane interne mitochondriale, qui synthétise l'ATP par couplage d’un transport de protons au travers de la membrane, en dissipant un gradient électrochimique de protons créé par la chaîne respiratoire. Cette réaction assure l’alimentation en énergie des processus biologiques cellulaires. Si la membrane mitochondriale se dépolarise, la réaction inverse d’hydrolyse d’ATP est rapidement bloquée par un inhibiteur soluble naturel de l’ATPase mitochondriale, IF1. Cette régulation efficace et réversible évite le gaspillage de l’énergie par la cellule. Chez la levure, IF1 est une petite protéine de 63 amino-acides. Elle se fixe sur l'une des trois interfaces catalytiques de l’ATP synthase et inhibe l’hydrolyse d’ATP. Bien que les structures cristallographiques des complexes F1-ATPase inhibés par IF1 aient été résolus, l'étape initiale de reconnaissance et celle du verrouillage d’IF1 restent peu claires au niveau moléculaire.Pendant ma thèse, nous nous sommes intéressés au mécanisme d’inhibition de l’ATPase par IF1. Par des analyses des structures disponibles et des alignements de séquence, nous avons sélectionné de nombreux résidus localisés dans différentes régions des sous-unités α et β de l'ATP synthase de Saccharomyces cerevisiae et susceptibles de participer au processus de fixation d'IF1. En utilisant le mutagenèse dirigée combinée à des experiences cinétiques, nous avons étudié les effects des mutations sur l’inhibition de l’ATP synthase par IF1 chez Saccharomyces cerevisiae. Dans ce travail, nous avons identifié des résidus ou motifs des sous-unités α et β de l’ATP synthase impliqués dans les étapes de reconaissance et/ou verrouillage d’IF1, ce qui nous permet de compléter les études structurales et d'esquisser un mécanisme de fixation d'IF1. / ATP synthase is an essential protein complex located in the mitochondrial inner membrane, which synthesize ATP by coupling to a rotary proton transport across the membrane at the expense of the electrochemical proton gradient created by the electron transport chain. This reaction guarantees the supply of energy to biological processes in a cell. When mitochondria get deenergized, i.e. the protomotive force across the mitochondrial inner membrane collapses, the ATP synthase switches from ATP synthesis to hydrolysis. This hydrolytic activity is then immediately prevented by a natural soluble mitochondrial ATPase inhibitor, IF1. This efficient reversible inhibition system protects cells from wasting energy. In yeast, IF1 is a small protein consisting of 63 amino acids. It binds to one of the three (αβ) catalytic interfaces of ATP synthase and thereby blocks the rotary catalysis. Although the crystal structure of the dead-end IF1 inhibited F1-ATPase complex has been resolved, IF1 initial binding and locking to ATPase still remain unclear events at the molecular level.During my thesis, we have been interested in the dynamic mechanism of ATPase inhibition by IF1. By means of analyses of published structures and protein sequence alignment, we selected numerous residues located in different regions of Saccharomyces cerevisiae ATP synthase α, β subunits, which might potentially paticipate in IF1 binding process. Using site-directed mutagenesis combined with kinetic experiments, we studied the effect of mutations of the selected candidates on the rate and extent of ATPase inhibition by IF1. In this way we identified residues or motifs in ATP synthase α, β subunits involved in IF1 recognition and/or locking steps, which allows complementing structural studies and drawing an outline of IF1 binding.

Mitochondrie

ATP synthase

Rotation

Force protomotrice

Chaîne de transport d'électrons

Inhibition d’IF1

Reconnaissance et verrouillage d’IF1

Mutagenèse

Cinétique

Kon

Koff

Kd

Mitochondria

ATP synthase

Rotation

Protomotive force

Electron transport chain

IF1 inhibition

IF1 recognition and locking

Mutagenesis

Kinetics

Kon

Koff

Kd

Fisiopatologia do Transtorno de Humor Bipolar e efeito do tratamento com lítio: enfoque em neuroproteção e função mitocondrial / Bipolar disorder pathophysiology and the effect of lithium treatment: focus on neuroprotection and mitochondrial function

Sousa, Rafael Augusto Teixeira de

14 March 2014

Introdução: Diversas evidências apontam para um papel da disfunção mitocondrial no Transtorno de Humor Bipolar (THB), mas pouco se sabe sobre isso no THB de início recente. Na mitocôndria a atividade da cadeia transportadora de elétrons (CTE) atua juntamente com o ciclo do ácido cítrico na produção de energia, mas não está claro se estão alteradas no THB. O DNA mitocondrial (DNAmt) codifica diversas proteínas da CTE e está associado ao estresse oxidativo, mas nunca foi avaliado em pacientes no THB in vivo. O estresse oxidativo está associado ao THB e à disfunção mitocondrial, mas não se sabe muito das atividades das enzimas antioxidantes no THB de início recente. O óxido nítrico (NO) é uma molécula com efeitos neuromoduladores, mas com um papel no THB ainda não elucidado. O lítio é um tratamento padrão-ouro no THB, tendo mostrado efeitos neuroprotetores. Apesar disso, pouco se conhece do efeito do lítio na CTE, nas enzimas do ciclo do ácido cítrico, no conteúdo de DNAmt e na regulação de NO em humanos. Também não está claro o papel antioxidante do lítio no THB. Metódos: Pacientes com THB em depressão (n=31), não medicados em sua maioria (84%), foram tratados por 6 semanas com lítio. Antes e depois do tratamento, verificaram-se em leucócitos as atividades dos complexos I-IV da CTE, atividades das enzimas citrato sintase, succinato desidrogenase e malato desidrogenase e também o conteúdo de DNAmt; em plasma foram analisados os níveis de NO, substâncias reativas ao ácido tiobarbitúrico (TBARS) e as atividades de catalase (CAT), glutationa peroxidase (GPx), superóxido dismutase (SOD) e razão de SOD/CAT. Os pacientes com depressão bipolar foram comparados com 28 controles saudáveis. Resultados: Em comparação com controles, os pacientes com THB tiveram um aumento de GPx (p < 0,001) e CAT (p=0,005) e uma diminuição de SOD/CAT (p=0,001), sem outras diferenças nos demais biomarcadores. Pacientes com THB I mostraram uma diminuição de citrato sintase (p=0,02) e uma discreta diminuição do conteúdo de DNAmt (p=0,05) em comparação com o THB II; o conteúdo de DNAmt esteve ligeiramente diminuído no THB I comparado com controles (p=0,05). Do início ao fim do tratamento com lítio houve aumento da atividade do complexo I da CTE (p=0,02), diminuição de TBARS (p=0,02) e SOD (p=0,03) e aumento de NO (p=0,02), sem haver alteração de outros parâmetros. Depois do tratamento, o TBARS se mostrou diminuído em respondedores comparados a não respondedores (p=0,02) e diminuído no THB II em comparação com o THB I (p=0,04). Discussão: No THB de início recente, houve poucas alterações em biomarcadores. Os achados sugerem aumento de CAT e GPx na depressão bipolar de início recente e uma diminuição de conteúdo mitocondrial no THB I comparado com o THB II, que devem ser confirmadas por outros estudos. Os resultados reforçam um papel neuroprotetor do lítio, sugerindo que a droga aumente a atividade do complexo I da CTE mitocondrial e aumente os níveis de NO na depressão bipolar. Além disso, o lítio reforçou o seu papel antioxidante e modulador das enzimas antioxidantes no THB / Background: Several evidences point to a role for mitochondrial dysfunction in Bipolar Disorder (BD), but few is known about it on short-term BD. In mitochondria the electron transport chain (ETC) acts jointly with citric acid cycle to produce energy, but it is not clear if they are altered in BD. Mitochondrial DNA (mtDNA) encodes several ETC proteins and is associated with oxidative stress, but it was never evaluated in BD in vivo. Oxidative stress is associated with BD and with mitochondrial dysfunction, but few is known about the activities of antioxidant enzymes in short-term BD. Nitric oxide (NO) is a molecule with neuromodulatory effects, but with an unclear role in BD. Lithium is a gold-standard treatment for BD, which has shown neuroprotective effects. However, few is known about lithium effect on ETC, citric acid cycle, mtDNA content, and NO regulation in humans. Also, lithium\'s antioxidant role in BD is unclear. Methods: Patients with BD depression (n=31) unmedicated in majority (84%) received lithium treatment for 6 weeks. Before and after treatment, in leukocytes the activities of ETC complex I-IV, citrate synthase, succinate dehydrogenase, and malate dehydrogenase, and mtDNA content were evaluated; in plasma, NO levels, thiobarbituric acid reactive substances (TBARS), the activities of catalase (CAT), glutathione peroxidase (GPx), and superoxide dismutase (SOD), and SOD/CAT ratio were evaluated. Bipolar depression patients were compared with 28 healthy controls. Results: When compared with controls, BD patients showed an increase in GPx (p < 0.001) and CAT (p=0.005) and a decrease in SOD/CAT (p=0.001), but showed no difference for other biomarkers. Patients with BD I showed a decrease in citrate synthase (p=0.02) and a slight decrease in mtDNA content (p=0.05) when compared to BD II; mtDNA content was slightly decreased in BD I compared to controls (p=0.05). From baseline to endpoint, there was an increase in ETC complex I activity (p=0.02), a decrease in TBARS (p=0.02) and SOD (p=0.03) and an increase in NO (p=0.02), without change in other parameters. After treatment, TBARS was decreased in responders compared to non-responders (p=0.02) and decreased in BD II compared to BD I (p=0.04). Discussion: In short-term BD few alterations were observed on biomarkers. The findings suggest increase on CAT and GPX in short-term bipolar depression and mitochondrial content decrease in BD I when compared to BD II, which deserve other studies for confirmation. The results reinforce a lithium\'s neuroprotective role and suggest that lithium increases ETC complex I activity and NO levels in bipolar depression. Moreover, lithium reinforced its role as antioxidant and as a modulator of antioxidant enzymes in BD

Bipolar disorder

Ciclo do ácido cítrico

Citric acid cycle

DNA mitocondrial

Estresse oxidativo

Fármacos neuroprotetores

Lithium

Lítio

Mitochondria

Mitochondrial DNA

Mitocôndrias

Neuroprotective agents

Nitric oxide

Oxidative stress

Óxido nítrico

Transtorno bipolar

Involvement of the chloroplastic photosynthetically electron transport in the differential expression of nuclear genes Methionine Sulfoxide Reductase (MSR) isoforms by excess light in Chlamydomonas reinhardtii

Tseng, Yu-Lu

28 June 2011

Methionine sulfoxide reductase A (MSRA) and MSRB are responsible for the repairing of methionine-R-sulfoxide (Met-S-SO) and methionine-S-sulfoxide (Met-R-SO) back to me-thionine, respectively. Five MSRA isoforms and four MSRB isoforms are discovered in the unicellular green alga Chlamydomonas reinhardtii. Whether high light regulates CrMSR ex-pression via photosynthetic electron transport (PET) was examined. By checking the se-quence of PCR product of each isoform, quantitative real-time primers were designed for discrimination of isoform expression. Light ≥ 300 £gE m-2 s-1 and PET inhibitors inhibited PSII activity (Fv/Fm, Fv&#x00B4;/Fm&#x00B4;) and photosynthetic O2 evolution rate, particularly 1,000 £gE m-2 s-1, in which it did not recover after 3 h. A transfer to dark decreased CrMSRA2, CrMSRA3, CrMSRB1.1, CrMSRB1.2, CrMSRB2.1 mRNA levels but increased CrMSRA4 mRNA levels. When exposed to 50, 300, 600, or 1,000 £gE m-2 s-1, CrMSRA2, CrMSRA3, CrMSRA5, CrMSRB1.1, CrMSRB2.1 and CrMSRB2.2 mRNA levels increased as light ≥ 300 £gE m-2 s-1, and concomitantly CrMSRA4 mRNA level decreased. Changes in mRNA levels increased as light intensity increased. The treatment of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) in 1,000 £gE m-2 s-1 inhibited high light effect, and the treatment of 2,5-dibromo-3-methyl-6- isopropyl-p- benzoquinone (DBMIB) in 50 £gE m-2 s-1 increased CrMSRA3, CrMSRA5 and CrMSRB2.2 mRNA levels but decreased CrMSRA4 mRNA level. The application of phena-zine methosulfate (PMS), an electron donor to P700+ that promotes cyclic electron transport, in 300 £gE m-2 s-1 enhanced the increase of CrMSRA3 and CrMSRA5 mRNA levels by high light but inhibited the decrease of CrMSRA4 mRNA level, reflecting a role of cyclic PET. The above results let us to draw a conclusion that plastoquinone as reduced status mediates the expression of CrMSRA3, CrMSRA4, CrMSRA5 and CrMSRB2.2 by high light. The im-plication of linear electron transport and cyclic electron transport on the regulation of CrMSR gene expression will be discussed.We speculated that the high light up-regulation of CrMSR mRNA expression offers the resistance of Chlamydomonas to photooxidative stress.

Chlamydomonas reinhardtii

Light intensity

Electron transport chain

PSII activity

Phenazine methosulfate (PMS)

Methionine sulfoxide redcuctase

Regulation of mitochondrial ATPase by its inhibitor protein IF1 in Saccharomyces cerevisiae

Wu, Qian

12 December 2013

ATP synthase is an essential protein complex located in the mitochondrial inner membrane, which synthesize ATP by coupling to a rotary proton transport across the membrane at the expense of the electrochemical proton gradient created by the electron transport chain. This reaction guarantees the supply of energy to biological processes in a cell. When mitochondria get deenergized, i.e. the protomotive force across the mitochondrial inner membrane collapses, the ATP synthase switches from ATP synthesis to hydrolysis. This hydrolytic activity is then immediately prevented by a natural soluble mitochondrial ATPase inhibitor, IF1. This efficient reversible inhibition system protects cells from wasting energy. In yeast, IF1 is a small protein consisting of 63 amino acids. It binds to one of the three (αβ) catalytic interfaces of ATP synthase and thereby blocks the rotary catalysis. Although the crystal structure of the dead-end IF1 inhibited F1-ATPase complex has been resolved, IF1 initial binding and locking to ATPase still remain unclear events at the molecular level.During my thesis, we have been interested in the dynamic mechanism of ATPase inhibition by IF1. By means of analyses of published structures and protein sequence alignment, we selected numerous residues located in different regions of Saccharomyces cerevisiae ATP synthase α, β subunits, which might potentially paticipate in IF1 binding process. Using site-directed mutagenesis combined with kinetic experiments, we studied the effect of mutations of the selected candidates on the rate and extent of ATPase inhibition by IF1. In this way we identified residues or motifs in ATP synthase α, β subunits involved in IF1 recognition and/or locking steps, which allows complementing structural studies and drawing an outline of IF1 binding.

Mitochondria

ATP synthase

Rotation

Protomotive force

Electron transport chain

IF1 inhibition

IF1 recognition and locking

Mutagenesis

Kinetics

Kon

Koff

Kd

Fisiopatologia do Transtorno de Humor Bipolar e efeito do tratamento com lítio: enfoque em neuroproteção e função mitocondrial / Bipolar disorder pathophysiology and the effect of lithium treatment: focus on neuroprotection and mitochondrial function

Rafael Augusto Teixeira de Sousa

14 March 2014

Introdução: Diversas evidências apontam para um papel da disfunção mitocondrial no Transtorno de Humor Bipolar (THB), mas pouco se sabe sobre isso no THB de início recente. Na mitocôndria a atividade da cadeia transportadora de elétrons (CTE) atua juntamente com o ciclo do ácido cítrico na produção de energia, mas não está claro se estão alteradas no THB. O DNA mitocondrial (DNAmt) codifica diversas proteínas da CTE e está associado ao estresse oxidativo, mas nunca foi avaliado em pacientes no THB in vivo. O estresse oxidativo está associado ao THB e à disfunção mitocondrial, mas não se sabe muito das atividades das enzimas antioxidantes no THB de início recente. O óxido nítrico (NO) é uma molécula com efeitos neuromoduladores, mas com um papel no THB ainda não elucidado. O lítio é um tratamento padrão-ouro no THB, tendo mostrado efeitos neuroprotetores. Apesar disso, pouco se conhece do efeito do lítio na CTE, nas enzimas do ciclo do ácido cítrico, no conteúdo de DNAmt e na regulação de NO em humanos. Também não está claro o papel antioxidante do lítio no THB. Metódos: Pacientes com THB em depressão (n=31), não medicados em sua maioria (84%), foram tratados por 6 semanas com lítio. Antes e depois do tratamento, verificaram-se em leucócitos as atividades dos complexos I-IV da CTE, atividades das enzimas citrato sintase, succinato desidrogenase e malato desidrogenase e também o conteúdo de DNAmt; em plasma foram analisados os níveis de NO, substâncias reativas ao ácido tiobarbitúrico (TBARS) e as atividades de catalase (CAT), glutationa peroxidase (GPx), superóxido dismutase (SOD) e razão de SOD/CAT. Os pacientes com depressão bipolar foram comparados com 28 controles saudáveis. Resultados: Em comparação com controles, os pacientes com THB tiveram um aumento de GPx (p < 0,001) e CAT (p=0,005) e uma diminuição de SOD/CAT (p=0,001), sem outras diferenças nos demais biomarcadores. Pacientes com THB I mostraram uma diminuição de citrato sintase (p=0,02) e uma discreta diminuição do conteúdo de DNAmt (p=0,05) em comparação com o THB II; o conteúdo de DNAmt esteve ligeiramente diminuído no THB I comparado com controles (p=0,05). Do início ao fim do tratamento com lítio houve aumento da atividade do complexo I da CTE (p=0,02), diminuição de TBARS (p=0,02) e SOD (p=0,03) e aumento de NO (p=0,02), sem haver alteração de outros parâmetros. Depois do tratamento, o TBARS se mostrou diminuído em respondedores comparados a não respondedores (p=0,02) e diminuído no THB II em comparação com o THB I (p=0,04). Discussão: No THB de início recente, houve poucas alterações em biomarcadores. Os achados sugerem aumento de CAT e GPx na depressão bipolar de início recente e uma diminuição de conteúdo mitocondrial no THB I comparado com o THB II, que devem ser confirmadas por outros estudos. Os resultados reforçam um papel neuroprotetor do lítio, sugerindo que a droga aumente a atividade do complexo I da CTE mitocondrial e aumente os níveis de NO na depressão bipolar. Além disso, o lítio reforçou o seu papel antioxidante e modulador das enzimas antioxidantes no THB / Background: Several evidences point to a role for mitochondrial dysfunction in Bipolar Disorder (BD), but few is known about it on short-term BD. In mitochondria the electron transport chain (ETC) acts jointly with citric acid cycle to produce energy, but it is not clear if they are altered in BD. Mitochondrial DNA (mtDNA) encodes several ETC proteins and is associated with oxidative stress, but it was never evaluated in BD in vivo. Oxidative stress is associated with BD and with mitochondrial dysfunction, but few is known about the activities of antioxidant enzymes in short-term BD. Nitric oxide (NO) is a molecule with neuromodulatory effects, but with an unclear role in BD. Lithium is a gold-standard treatment for BD, which has shown neuroprotective effects. However, few is known about lithium effect on ETC, citric acid cycle, mtDNA content, and NO regulation in humans. Also, lithium\'s antioxidant role in BD is unclear. Methods: Patients with BD depression (n=31) unmedicated in majority (84%) received lithium treatment for 6 weeks. Before and after treatment, in leukocytes the activities of ETC complex I-IV, citrate synthase, succinate dehydrogenase, and malate dehydrogenase, and mtDNA content were evaluated; in plasma, NO levels, thiobarbituric acid reactive substances (TBARS), the activities of catalase (CAT), glutathione peroxidase (GPx), and superoxide dismutase (SOD), and SOD/CAT ratio were evaluated. Bipolar depression patients were compared with 28 healthy controls. Results: When compared with controls, BD patients showed an increase in GPx (p < 0.001) and CAT (p=0.005) and a decrease in SOD/CAT (p=0.001), but showed no difference for other biomarkers. Patients with BD I showed a decrease in citrate synthase (p=0.02) and a slight decrease in mtDNA content (p=0.05) when compared to BD II; mtDNA content was slightly decreased in BD I compared to controls (p=0.05). From baseline to endpoint, there was an increase in ETC complex I activity (p=0.02), a decrease in TBARS (p=0.02) and SOD (p=0.03) and an increase in NO (p=0.02), without change in other parameters. After treatment, TBARS was decreased in responders compared to non-responders (p=0.02) and decreased in BD II compared to BD I (p=0.04). Discussion: In short-term BD few alterations were observed on biomarkers. The findings suggest increase on CAT and GPX in short-term bipolar depression and mitochondrial content decrease in BD I when compared to BD II, which deserve other studies for confirmation. The results reinforce a lithium\'s neuroprotective role and suggest that lithium increases ETC complex I activity and NO levels in bipolar depression. Moreover, lithium reinforced its role as antioxidant and as a modulator of antioxidant enzymes in BD

Ciclo do ácido cítrico

DNA mitocondrial

Estresse oxidativo

Fármacos neuroprotetores

Lítio

Mitocôndrias

Óxido nítrico

Transtorno bipolar

Bipolar disorder

Citric acid cycle

Lithium

Mitochondria

Mitochondrial DNA

Neuroprotective agents

Nitric oxide

Oxidative stress

Mitochondrial ROS direct the differentiation of murine pluripotent P19 cells

Pashkovskaia, Natalia, Gey, Uta, Rödel, Gerhard

13 December 2018

ROS are frequently associated with deleterious effects caused by oxidative stress. Despite the harmful effects of non-specific oxidation, ROS also function as signal transduction molecules that regulate various biological processes, including stem cell proliferation and differentiation. Here we show that mitochondrial ROS level determines cell fate during differentiation of the pluripotent stem cell line P19. As stem cells in general, P19 cells are characterized by a low respiration activity, accompanied by a low level of ROS formation. Nevertheless, we found that P19 cells contain fully assembled mitochondrial electron transport chain supercomplexes (respirasomes), suggesting that low respiration activity may serve as a protective mechanism against ROS. Upon elevated mitochondrial ROS formation, the proliferative potential of P19 cells is decreased due to longer S phase of the cell cycle. Our data show that besides being harmful, mitochondrial ROS production regulates the differentiation potential of P19 cells: elevated mitochondrial ROS level favours trophoblast differentiation, whereas preventing neuron differentiation. Therefore, our results suggest that mitochondrial ROS level serves as an important factor that directs differentiation towards certain cell types while preventing others.

info:eu-repo/classification/ddc/570

ddc:570