Imbalance of Mitochondrial Respiratory Chain Complexes in the Epidermis Induces Severe Skin Inflammation

Weiland, D., Brachvogel, B., Hornig-Do, H.-T., Neuhaus, J.F.G., Holzer, T., Tobin, Desmond J., Niessen, C.N., Wiesner, R.J., Baris, O.R.

01 September 2017

No / Accumulation of large-scale mitochondrial DNA (mtDNA) deletions and chronic, subclinical inflammation are concomitant during skin aging, thus raising the question of a causal link. To approach this, we generated mice expressing a mutant mitochondrial helicase (K320E-TWINKLE) in the epidermis to accelerate the accumulation of mtDNA deletions in this skin compartment. Mice displayed low amounts of large-scale deletions and a dramatic depletion of mtDNA in the epidermis and showed macroscopic signs of severe skin inflammation. The mtDNA alterations led to an imbalanced stoichiometry of mitochondrial respiratory chain complexes, inducing a unique combination of cytokine expression, causing a severe inflammatory phenotype, with massive immune cell infiltrates already before birth. Altogether, these data unraveled a previously unknown link between an imbalanced stoichiometry of the mitochondrial respiratory chain complexes and skin inflammation and suggest that severe respiratory chain dysfunction, as observed in few cells leading to a mosaic in aged tissues, might be involved in the development of chronic subclinical inflammation. / Deutsche Forschungsgemeinschaft (Wi 889/6-3 to RJW, SFB 829 A14 to RJW, Cologne Excellence Cluster on Cellular Stress Responses in Aging-associated Diseases–CECAD to RJW, BR2304/9-1 to BB, and SFB 829 A1, A5, and Z2 to CMN) and the Center of Molecular Medicine Cologne of the Medical Faculty (CMMC, to RJW)

Cellular substrates of iron overload cardiomyopathies

Baptista-Hon, Daniel Tomas

January 2011

Cardiomyopathies and arrhythmias are major causes of death in untreated hereditary haemochromatosis, acute iron poisoning and during secondary iron overload resulting from repeated blood transfusions in β-thalassaemia. Iron overload cardiomyopathies are associated with systolic and diastolic dysfunction, suggesting that Ca2+ homeostasis is impaired. However, the cellular mechanisms of these dysfunctions are unknown. The data presented in this thesis establishes for the first time iron effects on cardiomyocyte Ca2+ handling, as well as the potential cellular substrates responsible for this impairment during iron overload. Exposure of isolated rat ventricular cardiomyocytes to 200μM iron led to biphasic changes in systolic Ca2+ release. Phase 1: an initial reduction of systolic Ca2+ release followed by; Phase 2: increased Ca2+ release with arrhythmogenic spontaneous Ca2+ release, cell contracture and cell death. There is evidence that Fe2+ enters cardiomyocytes via L-type Ca2+ channels (LTCC) and reduces the Ca2+ trigger. The close apposition of LTCCs to cardiac ryanodine receptors (RyR2) suggests RyR2 may be a first target. Indeed RyR2 activity was drastically reduced on exposure to nanomolar [Fe2+] in single channel studies. Together with evidence that Fe2+ may reduce the Ca2+ trigger from LTCC, this is consistent with iron reducing sarcoplasmic reticulum (SR) Ca2+ release during Phase 1. In Phase 2, the presence of spontaneous Ca2+ release events is consistent with SR Ca2+ overload. Indeed, in single rat ventricular cardiomyocytes SR Ca2+ content was found to be increased by 27% during Phase 2. The cellular substrates responsible for this increased SR Ca2+ content were 2-fold: 1) through reduced extrusion via both the Na+ Ca2+ Exchanger (NCX) and Plasmalemmal Ca2+ ATPase (PMCA) and 2) through increased resequestration via the SR Ca2+ ATPase. Iron catalyses the production of reactive oxygen species (ROS) during the Fenton reaction. To investigate whether iron effects might be due to ROS, I used the cell permeant ROS scavenger Tempol. Tempol attenuated Phase 2 effects but Phase 1 effects were not affected. This is consistent with the hypothesis that Phase 1 effects were due to direct effects of Fe2+ affecting LTCC trigger and RyR2 function. The attenuation of Phase 2 effects suggests that ROS damage to key Ca2+ handling mechanisms, such as NCX and PMCA might account for a reduced Ca2+ extrusion and subsequent SR Ca2+ overload.

616.1

Bakteriální metabolismus morfinových alkaloidů / Morphine alkaloid metabolism in bacteria

Zahradník, Jiří

January 2016

Morphine alkaloids and their derivatives are pharmaceutically important substances. Huge production and consumption of these compounds predetermines them to be significant pollutants in the environment. Some of them have been detected in surface waters. The aim of this study was to characterize effects of morphine alkaloids on the physiology of three model organisms: Agrobacterium sp. R89-1, Escherichia coli XL-1 (Blue), and Raoultella sp. kDF8, and elucidation of the mechanisms leading to toxicity. The biotransformation potential and utilization ability were characterized for model organisms. It was demonstrated that the microorganism Agrobacterium sp. R89-1 is capable of rapid biotransformation of codeine to its 14-OH derivatives. The manifestation of morphine compounds toxic effects for the strain R89-1 is the highest. In contrast, microorganism Raoultella sp. KDF8 is able to utilize codeine as a carbon and energy source. The accumulation of 14-OH-derivatives was not observed. Escherichia coli XL-1 (Blue) is not able to biotransform or utilize codeine. Α, β-unsaturated ketones (morphinone, codeinone, 14-OH-morphinone and 14-OH-codeinone) were found as a most toxic intermediates of codeine metabolism. Bacterial cell growth (strains R89-1 and KDF8) in the presence of codeine is characteristic with...

Avaliação do efeito protetor do carvedilol na toxicidade mitocondrial renal induzida pela cisplatina em ratos / Evaluation of the protective effect of carvedilol against the renal mitochondrial toxicity induced by cisplatin in rats

Rodrigues, Maria Augusta Carvalho

26 May 2009

A cisplatina (cis-diaminodicloroplatina II) é um efetivo agente anticâncer, porém seu uso clínico é altamente limitado, predominantemente devido à sua nefrotoxicidade. Muitos estudos têm demonstrado que a cisplatina causa disfunção mitocondrial em células epiteliais renais devido à ação de espécies reativas de oxigênio tais como ânions superóxido e radicais hidroxila. A proteção seletiva das mitocôndrias renais contra espécies reativas de oxigênio geradas pela cisplatina é fundamental na quimioterapia de pacientes com câncer. Vários estudos têm sugerido que o carvedilol é capaz de proteger contra a toxicidade mitocondrial cardíaca induzida pelo quimioterápico doxorubicina. Assim, no presente estudo investigou-se o potencial protetor deste fármaco contra a toxicidade mitocondrial renal induzida pela cisplatina, bem como os mecanismos moleculares envolvidos nesta proteção. Foram estudados 4 grupos (n=6, cada) de ratos Wistar machos tratados da seguinte forma: (i) Grupo controle: uma injeção intraperitoneal (i.p.) de DMSO (0,2mL/200g, i.p.) imediatamente antes da injeção de solução salina isotônica (2 ml/200g, i.p.) e posteriormente uma injeção diária de DMSO (0,2mL/200g, i.p.) em dois dias consecutivos; (ii) Grupo cisplatina (CISP): uma injeção de cisplatina (10 mg/kg, i.p.); (iii) Grupo carvedilol (CV): uma injeção de carvedilol (1 mg/kg, i.p.), seguida de uma injeção diária de carvedilol em dois dias consecutivos (1 mg/Kg, i.p) e (iv) Grupo carvedilol + cisplatina (CV+CISP): uma injeção de carvedilol (1mg/kg, i.p.), imediatamente antes da injeção de cisplatina (10 mg/Kg, i.p.) seguida de uma injeção diária de carvedilol nos dois dias seguintes (1 mg/Kg, i.p.). Os animais foram sacrificados 72 horas após o início do tratamento. O grupo CV+CISP apresentou uma significativa redução na lesão renal, marcada pela diminuição da concentração de uréia e creatinina plasmáticas, quando comparado ao grupo CISP. A avaliação da função mitocondrial comprovou o efeito protetor do carvedilol contra a toxicidade mitocondrial renal da cisplatina através da significativa melhora nos valores da (i) RCR, (ii) do consumo de oxigênio no estado 3 e (iii) da razão ADP/O. Além disso, no grupo CV+CISP o potencial de membrana mitocondrial e a captação de cálcio mitocondrial foram preservados. Adicionalmente, a redução da oxidação do NADPH, da cardiolipina, da glutationa e das proteínas sulfidrilas, bem como a redução na formação de MDA no grupo CV+CISP sugerem efeito protetor do carvedilol contra o estresse oxidativo mitocondrial. O grupo CV+CISP também apresentou menor ativação da caspase-3, o que sugere menor indução de apoptose. Os grupos CISP e CV+CISP apresentaram concentrações semelhantes de platina na suspensão mitocondrial renal, indicando que o mecanismo de proteção do carvedilol provavelmente não envolve a formação de complexos e a subseqüente inativação da cisplatina. Os resultados do presente estudo são promissores, pois o carvedilol é um fármaco de uso seguro e já estabelecido na clínica e a comprovação do seu efeito protetor contribuirá para o desenvolvimento de novas estratégias de prevenção dos danos nefrotóxicos da cisplatina. / Cisplatin (cis-diamminedichloridoplatinum II) is an affective anticancer agent; however its clinical use is highly limited, predominantly due to its nephrotoxicity. Many studies have shown that cisplatin cause mitochondrial dysfunction in renal epithelial cells due to the generation of reactive oxygen species, such as superoxide anions and hydroxyl radicals. The selective protection of the renal mitochondria against the reactive oxygen species generated by cisplatin is of critical importance in the chemotherapy of cancer patients. Some studies have suggested that carvedilol can protect against the cardiac mitochondrial toxicity induced by the chemotherapeutic agent doxorubicin. Therefore, in the present study we investigated the protective effect of carvedilol against renal mitochondrial toxicity, as well as the molecular mechanisms involved in this protection. We studied 4 groups (n=6, each) of male Wistar rats treated as follows: (i) Control group: one injection of DMSO (0,2 mL/200g body weight, i.p.), intraperitoneal injection (i.p.), immediately before the injection of isotonic saline solution (2mL/200g body weight) followed by one injection of DMSO (0,2 mL/200g body weight, i.p.) in the two following days; (ii) Cisplatin group (CISP): one injection of cisplatin (10 mg/kg body weight, i.p.); (iii) Carvedilol group (CV): one injection of carvedilol (CV) (1mg/kg body weight, i.p.) in three consecutive days and (iv) Carvedilol + Cisplatin group (CV+CISP): one injection of carvedilol (1mg/kg, body weight, i.p.) immediately before the injection of cisplatin (10mg/kg, body weight, i.p.), followed by one injection of carvedilol (1mg/kg, body weight, i.p.) in the two following days. Animals were killed 72h after the beginning of the treatment. CV+CISP group presented a significantly reduced renal injury, marked by the decrease of urea and creatinine plasmatic levels, as compared to the CISP group. The evaluation of the mitochondrial function showed the protective effect of carvedilol against the renal mitochondria toxicity induced by cisplatin, as demonstrated by the improvement in the values of (i) RCR; (ii) the oxygen consumption on state 3 respiration and ADP/O ratio. Besides that, in the CV+CISP group the mitochondrial membrane potential and the mitochondrial calcium uptake were preserved. Additionally, the lower oxidation of NADPH, cardiolipin, glutathione and sulfhydryl proteins, as well as the lower values of MDA in the CV+CISP group, suggests a protective effect of carvedilol against the mitochondrial oxidative stress. CV+CISP group also presented lower values of caspase 3, which suggests lower induction of apoptosis. The groups CISP and CV+CISP presented a similar platinum concentration in the mitochondrial suspension, which indicates that the protective mechanism of carvedilol probably does not involve complex formation with cisplatin and its ensuing inactivation. The present results are promising, since carvedilol is a safe drug, which is currently used in the clinical practice and the evidence of its protective effect will contribute to the development of new strategies to prevent the nephrotoxic damage of cisplatin.

carvedilol

carvedilol

cisplatin

cisplatina

citoproteção

cytoprotection

ERO (espécies reativas de oxigênio)

mitochondria

mitocôndria

nefrotoxicidade

nephrotoxicity

ROS (reactive oxygen species)

Avaliação do efeito protetor do carvedilol na toxicidade mitocondrial renal induzida pela cisplatina em ratos / Evaluation of the protective effect of carvedilol against the renal mitochondrial toxicity induced by cisplatin in rats

Maria Augusta Carvalho Rodrigues

26 May 2009

A cisplatina (cis-diaminodicloroplatina II) é um efetivo agente anticâncer, porém seu uso clínico é altamente limitado, predominantemente devido à sua nefrotoxicidade. Muitos estudos têm demonstrado que a cisplatina causa disfunção mitocondrial em células epiteliais renais devido à ação de espécies reativas de oxigênio tais como ânions superóxido e radicais hidroxila. A proteção seletiva das mitocôndrias renais contra espécies reativas de oxigênio geradas pela cisplatina é fundamental na quimioterapia de pacientes com câncer. Vários estudos têm sugerido que o carvedilol é capaz de proteger contra a toxicidade mitocondrial cardíaca induzida pelo quimioterápico doxorubicina. Assim, no presente estudo investigou-se o potencial protetor deste fármaco contra a toxicidade mitocondrial renal induzida pela cisplatina, bem como os mecanismos moleculares envolvidos nesta proteção. Foram estudados 4 grupos (n=6, cada) de ratos Wistar machos tratados da seguinte forma: (i) Grupo controle: uma injeção intraperitoneal (i.p.) de DMSO (0,2mL/200g, i.p.) imediatamente antes da injeção de solução salina isotônica (2 ml/200g, i.p.) e posteriormente uma injeção diária de DMSO (0,2mL/200g, i.p.) em dois dias consecutivos; (ii) Grupo cisplatina (CISP): uma injeção de cisplatina (10 mg/kg, i.p.); (iii) Grupo carvedilol (CV): uma injeção de carvedilol (1 mg/kg, i.p.), seguida de uma injeção diária de carvedilol em dois dias consecutivos (1 mg/Kg, i.p) e (iv) Grupo carvedilol + cisplatina (CV+CISP): uma injeção de carvedilol (1mg/kg, i.p.), imediatamente antes da injeção de cisplatina (10 mg/Kg, i.p.) seguida de uma injeção diária de carvedilol nos dois dias seguintes (1 mg/Kg, i.p.). Os animais foram sacrificados 72 horas após o início do tratamento. O grupo CV+CISP apresentou uma significativa redução na lesão renal, marcada pela diminuição da concentração de uréia e creatinina plasmáticas, quando comparado ao grupo CISP. A avaliação da função mitocondrial comprovou o efeito protetor do carvedilol contra a toxicidade mitocondrial renal da cisplatina através da significativa melhora nos valores da (i) RCR, (ii) do consumo de oxigênio no estado 3 e (iii) da razão ADP/O. Além disso, no grupo CV+CISP o potencial de membrana mitocondrial e a captação de cálcio mitocondrial foram preservados. Adicionalmente, a redução da oxidação do NADPH, da cardiolipina, da glutationa e das proteínas sulfidrilas, bem como a redução na formação de MDA no grupo CV+CISP sugerem efeito protetor do carvedilol contra o estresse oxidativo mitocondrial. O grupo CV+CISP também apresentou menor ativação da caspase-3, o que sugere menor indução de apoptose. Os grupos CISP e CV+CISP apresentaram concentrações semelhantes de platina na suspensão mitocondrial renal, indicando que o mecanismo de proteção do carvedilol provavelmente não envolve a formação de complexos e a subseqüente inativação da cisplatina. Os resultados do presente estudo são promissores, pois o carvedilol é um fármaco de uso seguro e já estabelecido na clínica e a comprovação do seu efeito protetor contribuirá para o desenvolvimento de novas estratégias de prevenção dos danos nefrotóxicos da cisplatina. / Cisplatin (cis-diamminedichloridoplatinum II) is an affective anticancer agent; however its clinical use is highly limited, predominantly due to its nephrotoxicity. Many studies have shown that cisplatin cause mitochondrial dysfunction in renal epithelial cells due to the generation of reactive oxygen species, such as superoxide anions and hydroxyl radicals. The selective protection of the renal mitochondria against the reactive oxygen species generated by cisplatin is of critical importance in the chemotherapy of cancer patients. Some studies have suggested that carvedilol can protect against the cardiac mitochondrial toxicity induced by the chemotherapeutic agent doxorubicin. Therefore, in the present study we investigated the protective effect of carvedilol against renal mitochondrial toxicity, as well as the molecular mechanisms involved in this protection. We studied 4 groups (n=6, each) of male Wistar rats treated as follows: (i) Control group: one injection of DMSO (0,2 mL/200g body weight, i.p.), intraperitoneal injection (i.p.), immediately before the injection of isotonic saline solution (2mL/200g body weight) followed by one injection of DMSO (0,2 mL/200g body weight, i.p.) in the two following days; (ii) Cisplatin group (CISP): one injection of cisplatin (10 mg/kg body weight, i.p.); (iii) Carvedilol group (CV): one injection of carvedilol (CV) (1mg/kg body weight, i.p.) in three consecutive days and (iv) Carvedilol + Cisplatin group (CV+CISP): one injection of carvedilol (1mg/kg, body weight, i.p.) immediately before the injection of cisplatin (10mg/kg, body weight, i.p.), followed by one injection of carvedilol (1mg/kg, body weight, i.p.) in the two following days. Animals were killed 72h after the beginning of the treatment. CV+CISP group presented a significantly reduced renal injury, marked by the decrease of urea and creatinine plasmatic levels, as compared to the CISP group. The evaluation of the mitochondrial function showed the protective effect of carvedilol against the renal mitochondria toxicity induced by cisplatin, as demonstrated by the improvement in the values of (i) RCR; (ii) the oxygen consumption on state 3 respiration and ADP/O ratio. Besides that, in the CV+CISP group the mitochondrial membrane potential and the mitochondrial calcium uptake were preserved. Additionally, the lower oxidation of NADPH, cardiolipin, glutathione and sulfhydryl proteins, as well as the lower values of MDA in the CV+CISP group, suggests a protective effect of carvedilol against the mitochondrial oxidative stress. CV+CISP group also presented lower values of caspase 3, which suggests lower induction of apoptosis. The groups CISP and CV+CISP presented a similar platinum concentration in the mitochondrial suspension, which indicates that the protective mechanism of carvedilol probably does not involve complex formation with cisplatin and its ensuing inactivation. The present results are promising, since carvedilol is a safe drug, which is currently used in the clinical practice and the evidence of its protective effect will contribute to the development of new strategies to prevent the nephrotoxic damage of cisplatin.

carvedilol

cisplatina

citoproteção

ERO (espécies reativas de oxigênio)

mitocôndria

nefrotoxicidade

carvedilol

cisplatin

cytoprotection

mitochondria

nephrotoxicity

ROS (reactive oxygen species)

The Rtg1 and Rtg3 proteins are novel transcription factors regulated by the yeast hog1 mapk upon osmotic stress

Noriega Esteban, Núria

27 February 2009

La adaptación de la levadura Saccharomyces cerevisiae a condiciones de alta osmolaridad está mediada por la vía de HOG ((high-osmolarity glycerol). La activación de esta vía induce una serie de respuestas que van a permitir la supervivencia celular en respuesta a estrés. La regulación génica constituye una respuesta clave para dicha supervivencia. Se han descrito cinco factores de transcripción regulados por Hog1 en respuesta a estrés osmótico. Sin embargo, éstos no pueden explicar la totalidad de los genes regulados por la MAPK Hog1. En el presente trabajo describimos cómo el complejo transcripcional formado por las proteínas Rtg1 y Rtg3 regula, a través de la quinasa Hog1, la expresión de un conjunto específico de genes. Hog1 fosforila Rtg1 y Rtg3, aunque ninguna de estas fosforilaciones son esenciales para regulación transcripcional en respuesta a estrés. Este trabajo también muestra cómo la deleción de proteínas RTG provoca osmosensibilidad celular, lo que indica que la integridad de la vía de RTG es esencial para la supervivencia celular frente a un estrés osmótico. / In Saccharomyces cerevisiae the adaptation to high osmolarity is mediated by the HOG (high-osmolarity glycerol) pathway, which elicits different cellular responses required for cell survival upon osmostress. Regulation of gene expression is a major adaptative response required for cell survival in response to osmotic stress. At least five transcription factors have been reported to be controlled by the Hog1 MAPK. However, they cannot account for the regulation of all of the genes under the control of the Hog1 MAPK. Here we show that the Rtg1/3 transcriptional complex regulates the expression of specific genes upon osmostress in a Hog1-dependent manner. Hog1 phosphorylates both Rtg1 and Rtg3 proteins. However, none of these phosphorylations are essential for the transcriptional regulation upon osmostress. Here we also show that the deletion of RTG proteins leads to osmosensitivity at high osmolarity, suggesting that the RTG-pathway integrity is essential for cell survival upon stress.

OD: optical density

NAD+: nicotinamide adenine dinucleotide

MAPK: mitogen activated protein kinase

HOG: high osmolarity glycerol

ERC: extrachromosomal rDNA circles

CDK: cyclin dependent kinase

DNA: desoxirribobucleic acid

ATP: adenosine triphosphate

AMP: adenosine monophosphate

TOR: Diana de la rapamicina

STRE element de resposta a l'estrés

ROS: especies reactives de l'oygen

rDNA: DNA risbosomal

OD: densitat òptica

NAD+: nicotinàmida adenina dinucleòtid

HOG: osmolaritat elevada de glicerol

rDNA: risbosomal DNA

ERC: cercle d'rDNA extracromosòmic

DNA: àcid desoxirriblonucleic

CDK: Kinassa dependent de ciclines

ATP: trifosfat d'adenosina

AMP: monofosfat d'adenosina

ROS: reactive oxygen species

SAPK: stress activated protein kinase

STRE: stress response element

TOR: target of rapamycin

575

58

SCF cdc4 regulates msn2 and msn4 dependent gene expression to counteract hog1 induced lethality

Vendrell Arasa, Alexandre

16 January 2009

L'activació sostinguda de Hog1 porta a una inhibició del creixement cel·lular. En aquest treball, hem observat que el fenotip de letalitat causat per l'activació sostinguda de Hog1 és parcialment inhibida per la mutació del complexe SCFCDC4. La inhibició de la mort causada per l'activació sostinguda de Hog1 depèn de la via d'extensió de la vida. Quan Hog1 s'activa de manera sostinguda, la mutació al complexe SCFCDC4 fa que augmenti l'expressió gènica depenent de Msn2 i Msn4 que condueix a una sobreexpressió del gen PNC1 i a una hiperactivació de la deacetilassa Sir2. La hiperactivació de Sir2 és capaç d'inhibir la mort causada per l'activació sostinguda de Hog1. També hem observat que la mort cel·lular causada per l'activació sostinguda de Hog1 és deguda a una inducció d'apoptosi. L'apoptosi induïda per Hog1 és inhibida per la mutació al complexe SCFCDC4. Per tant, la via d'extensió de la vida és capaç de prevenir l'apoptosi a través d'un mecanisme desconegut. / Sustained Hog1 activation leads to an inhibition of cell growth. In this work, we have observed that the lethal phenotype caused by sustained Hog1 activation is prevented by SCFCDC4 mutants. The prevention of Hog1-induced cell death by SCFCDC4 mutation depends on the lifespan extension pathway. Upon sustained Hog1 activation, SCFCDC4 mutation increases Msn2 and Msn4 dependent gene expression that leads to a PNC1 overexpression and a Sir2 deacetylase hyperactivation. Then, hyperactivation of Sir2 is able to prevent cell death caused by sustained Hog1 activation. We have also observed that cell death upon sustained Hog1 activation is due to an induction of apoptosis. The apoptosis induced by Hog1 is decreased by SCFCDC4 mutation. Therefore, lifespan extension pathway is able to prevent apoptosis by an unknown mechanism.

STRE: stress response element

TOR: target of rapamycin

SAPK: stress activated protein kinase

ROS: reactive oxygen species

PCD: programmed cell death

rDNA: risbosomal DNA

PAK: p21 activated kinase

NAM: nicotinamide

OD: optical density

MEF2C: myocyte enhancer factor 2C

NAD+: nicotinamide adenine dinucleotide

MAPK: mitogen activated protein kinase

SRF from homo sapiens

agamous fromaArabidopsis thaliana

saccharomyces cerevisiae

IAP: inhibitor of apoptosis proteins

HOG: high osmolarity glycerol

FACS: fluorescent-activated cell sorting

ERC: extrachromosomal rDNA circles

DUBs: deubiquitinases

CR: caloric restriction

DNA: desoxirribobucleic acid

CDK: cyclin dependent kinase

ATP: adenosine triphosphate

AMP: adenosine monophosphate

AIF: apoptosis-inducing factor

TOR: Diana de la rapamicina

STRE element de resposta a l'estrés

ROS: especies reactives de l'oygen

rDNA: DNA risbosomal

PCD: mort cel·lular programada

PAK: kinassa activada per p21

OD: densitat òptica

NAM: nicotinàmida

NAD+: nicotinàmida adenina dinucleòtid

MEF2C: factor 2C activador del miócits

i SRF d'Homo sapiens

del rèptil Antirrhinum majus

AGAMOUS d'Arabidopsis thaliana

DEFICIENS

Saccharomyces cerevisiae

IAP: inhibidor de proteins d'apoptosi

HOG: Osmolaritat elevada de glicerol

ERC: cercle d'rDNA extracromosòmic

DUB: deubiquitinassa

DNA: Àcid desoxirriblonucleic

CR: restricció calòrica

CDK: kinassa dependent de ciclines

ATP: trifosfat d'adenosina

AMP: monofosfat d'adenosina

AIF: factor inductor d'apoptosi

576