Role of mitochondria in the pheromone- and amiodarone-induced programmed death of yeast

Pozniakovsky, Andrei; Knorre, Dmitry A.; Маркова, О. В.; Hyman, Anthony A.; Vp, Skulachev; Severin, Fedor F.

doi:10.1083/jcb.200408145

Cited by 247 publications

(225 citation statements)

References 79 publications

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“…Actually, similar to mammalian cells, yeast apoptosis is sometimes accompanied by a sharp transient increase of mitochondrial membrane potential that can directly cause accumulation of ROS [33]. A decrease of mitochondrial potential is considered a general marker for in vivo ageing both in mammals and yeast cells [34]. In fact, DASPMI staining performed upon human VDAC-expressing strains in cells aged 3 days showed a dramatic decrease of mitochondrial potential, with an especially negative decrease for VDAC3 carrying cells (Fig.…”

Section: Swapping Of the N-terminal Domain Of Vdac3 With The Same Dommentioning

confidence: 92%

Swapping of the N‐terminus of VDAC1 with VDAC3 restores full activity of the channel and confers anti‐aging features to the cell

et al. 2010

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a b s t r a c tVoltage-dependent anion-selective channels (VDACs) are pore-forming proteins allowing the permeability of the mitochondrial outer membrane. The VDAC3 isoform is the least abundant and least active in a complementation assay performed in a yeast strain devoid of porin-1. We swapped the VDAC3 N-terminal 20 amino acids with homologous sequences from the other isoforms. The substitution of the VDAC3 N-terminus with the VDAC1 N-terminus caused the chimaera to become more active than VDAC1. The VDAC2 N-terminus improved VDAC3 activity, though to a lesser extent. The VDAC3 carrying the VDAC1 N-terminus was able to complement the lack of the yeast porin in mitochondrial respiration and in modulation of reactive oxygen species (ROS). This chimaera increased life span, indicating a more efficient bioenergetic metabolism and/or a better protection from ROS.

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Section: Swapping Of the N-terminal Domain Of Vdac3 With The Same Dommentioning

confidence: 92%

Swapping of the N‐terminus of VDAC1 with VDAC3 restores full activity of the channel and confers anti‐aging features to the cell

et al. 2010

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“…Its cytosolic concentration rises following amiodarone (an antiarrhythmic drug) or a-factor-induced apoptosis, eventually leading to mitochondrial fragmentation in a process that depends on the yeast suicide protein Ysp1p. 36 An additional link between yeast death and Ca 2 þ is mediated by the calcineurin/calmodulin system, which is connected to ER stress regulation. 37 In nature, the functional potential of yeast undergoing apoptosis is hijacked for different purposes (see Figure 2).…”

Section: Triggering Yeast Apoptosismentioning

confidence: 99%

“…40 Treatment of yeast cells with amiodarone also triggers yeast cell death, in this case via the mitochondrial pathway and preceded by a Ca 2 þ boost. 36 The transcriptional response of yeast cells to amiodarone treatment includes two signatures: one that resembles a Ca 2 þ stress response that is accompanied by downregulation of genes involved in all stages of cell-cycle control, and another that is Ca 2 þ -independent and affects nutrient-responsive genes. 41 Diverse other antitumor agents, such as 5-fluorouracil or coumarin, shown to be cytotoxic for yeast, 39 need further investigation regarding the induced mode of cell death in order to establish a possible link to apoptosis.…”

Section: Triggering Yeast Apoptosismentioning

confidence: 99%

“…Interaction of the pheromone with its receptor (Ste2p or Ste3p) results in activation of the MAP kinase-signaling cascade (which involves the key kinase Ste20p), subsequent increase of intracellular Ca 2 þ , and a rise in mitochondrial activity, followed by cytochrome c release and apoptosis. 12,36 In contrast, death caused by elevated concentrations of pheromone lacks certain hallmarks of apoptosis. 42 Of note, sporulation following meiosis of diploid cells is coupled to apoptosis as well.…”

Section: Triggering Yeast Apoptosismentioning

confidence: 99%

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Apoptosis in yeast: triggers, pathways, subroutines

et al. 2010

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A cell's decision to die is controlled by a sophisticated network whose deregulation contributes to the pathogenesis of multiple diseases including neoplastic and neurodegenerative disorders. The finding, more than a decade ago, that baker's yeast (Saccharomyces cerevisiae) can undergo apoptosis uncovered the possibility to investigate this mode of programmed cell death (PCD) in a model organism that combines both technical advantages and a eukaryotic 'cell room.' Since then, numerous exogenous and endogenous triggers have been found to induce yeast apoptosis and multiple yeast orthologs of crucial metazoan apoptotic regulators have been identified and characterized at the molecular level. Such apoptosis-relevant orthologs include proteases such as the yeast caspase as well as several mitochondrial and nuclear proteins that contribute to the execution of apoptosis in a caspase-independent manner. Additionally, physiological scenarios such as aging and failed mating have been discovered to trigger apoptosis in yeast, providing a teleological interpretation of PCD affecting a unicellular organism. Due to its methodological and logistic simplicity, yeast constitutes an ideal model organism that is efficiently helping to decipher the cell death regulatory network of higher organisms, including the switches between apoptotic, autophagic, and necrotic pathways of cellular catabolism. Here, we provide an overview of the current knowledge about the apoptotic subroutine of yeast PCD and its regulation.

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“…Thus, mutational disruption of the S. cerevisiae mitochondrial electron transport chain reduces apoptosis caused by copper and manganese (Liang & Zhou, 2007), amiodarone (Pozniakovsky et al, 2005), acetic acid (Ludovico et al, 2002), hyperosmotic stress (Silva et al, 2005) and chronological ageing (Li et al, 2006). We tested how the absence of Ndi1p (mitochondrial inner membrane-associated NADH dehydrogenase) or Cox12p (part of complex IV in the electron transport chain) affected selenite-induced apoptosis.…”

Section: Selenite-mediated Apoptosis Requires Aif1p Activitymentioning

confidence: 99%

Selenite-induced cell death in Saccharomyces cerevisiae: protective role of glutaredoxins

2010

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Unlike in higher organisms, selenium is not essential for growth in Saccharomyces cerevisiae. In this species, it causes toxic effects at high concentrations. In the present study, we show that when supplied as selenite to yeast cultures growing under fermentative metabolism, its effects can be dissected into two death phases. From the time of initial treatment, it causes loss of membrane integrity and genotoxicity. Both effects occur at higher levels in mutants lacking Grx1p and Grx2p than in wild-type cells, and are reversed by expression of a cytosolic version of the membrane-associated Grx7p glutaredoxin. Grx7p can also rescue the high levels of protein carbonylation damage that occur in selenite-treated cultures of the grx1 grx2 mutant. After longer incubation times, selenite causes abnormal nuclear morphology and the appearance of TUNELpositive cells, which are considered apoptotic markers in yeast cells. This effect is independent of Grx1p and Grx2p. Therefore, the protective role of the two glutaredoxins is restricted to the initial stages of selenite treatment. Lack of Yca1p metacaspase or of a functional mitochondrial electron transport chain only moderately diminishes apoptotic-like death by selenite. In contrast, seleniteinduced apoptosis is dependent on the apoptosis-inducing factor Aif1p. In the absence of the latter, intracellular protein carbonylation is reduced after prolonged selenite treatment, supporting the supposition that part of the oxidative damage is contributed by apoptotic cells. INTRODUCTIONSelenium (Se) is a trace element which may have anticarcinogenic action at low concentrations (Letavayová et al., 2006). The essential character of Se in the mammalian diet is related to its presence as selenocysteine in a number of selenoproteins, such as thioredoxin reductases and glutathione peroxidases (Lu & Holmgren, 2009). These enzymes act in the defence against oxidative stress. In contrast, at high concentrations, Se is toxic because it generates oxidative stress and provokes DNA damage (Hatfield et al., 2006;Letavayová et al., 2006). Among the Se compounds that may come into contact with cells, selenite is a prooxidant because it undergoes glutathionemediated reduction to hydrogen selenide with the subsequent formation of superoxide radicals, which can undergo conversion into other reactive oxygen species (ROS) Spallholz, 1997;Tarze et al., 2007). Saccharomyces cerevisiae is a suitable organism to study the toxic properties of Se and the cellular mechanisms which prevent or repair its effects, without the interference due to an Se requirement for selenoproteins. In fact, S. cerevisiae, and fungi in general, do not contain selenoproteins and therefore Se is not essential for these organisms (Lu & Holmgren, 2009). High concentrations of Se cause DNA double-strand breaks in exponentially growing S. cerevisiae cells (Letavayová et al., 2008) and RAD9-dependent cell cycle arrest (Pinson et al., 2000). Accordingly, yeast mutants defective in the RAD9-mediated DNA repair pathway or the RAD6/RAD...

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Role of mitochondria in the pheromone- and amiodarone-induced programmed death of yeast

Cited by 247 publications

References 79 publications

Swapping of the N‐terminus of VDAC1 with VDAC3 restores full activity of the channel and confers anti‐aging features to the cell

Swapping of the N‐terminus of VDAC1 with VDAC3 restores full activity of the channel and confers anti‐aging features to the cell

Apoptosis in yeast: triggers, pathways, subroutines

Selenite-induced cell death in Saccharomyces cerevisiae: protective role of glutaredoxins

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