Sandra M. Cardoso

SIRT3 opposes reprogramming of cancer cell metabolism through HIF1α destabilization.

Tumor cells exhibit aberrant metabolism characterized by high glycolysis even in the presence of oxygen. This metabolic reprogramming, known as the Warburg effect, provides tumor cells with the substrates required for biomass generation. Here, we show that the mitochondrial NAD-dependent deacetylase SIRT3 is a crucial regulator of the Warburg effect. Mechanistically, SIRT3 mediates metabolic reprogramming by destabilizing hypoxia-inducible factor-1α (HIF1α), a transcription factor that controls glycolytic gene expression. SIRT3 loss increases reactive oxygen species production, leading to HIF1α stabilization. SIRT3 expression is reduced in human breast cancers, and its loss correlates with the upregulation of HIF1α target genes. Finally, we find that SIRT3 overexpression represses glycolysis and proliferation in breast cancer cells, providing a metabolic mechanism for tumor suppression.

Mitochondria dysfunction of Alzheimer's disease cybrids enhances Aβ toxicity

Alzheimers disease (AD) brain reveals high rates of oxygen consumption and oxidative stress, altered antioxidant defences, increased oxidized polyunsaturated fatty acids, and elevated transition metal ions. Mitochondrial dysfunction in AD is perhaps relevant to these observations, as such may contribute to neurodegenerative cell death through the formation of reactive oxygen species (ROS) and the release of molecules that initiate programmed cell death pathways. In this study, we analyzed the effects of beta‐amyloid peptide (Aβ) on human teratocarcinoma (NT2) cells expressing endogenous mitochondrial DNA (mtDNA), mtDNA from AD subjects (AD cybrids), and mtDNA from age‐matched control subjects (control cybrids). In addition to finding reduced cytochrome oxidase activity, elevated ROS, and reduced ATP levels in the AD cybrids, when these cell lines were exposed to Aβ 1–40 we observed excessive mitochondrial membrane potential depolarization, increased cytoplasmic cytochrome c, and elevated caspase‐3 activity. When exposed to Aβ, events associated with programmed cell death are activated in AD NT2 cybrids to a greater extent than they are in control cybrids or the native NT2 cell line, suggesting a role for mtDNA‐derived mitochondrial dysfunction in AD degeneration.

Cytochrome c oxidase is decreased in Alzheimer's disease platelets.

Cytochrome c oxidase (COX) activity reportedly is reduced in Alzheimers disease (AD) brain and platelets. The reasons for the defect in either tissue are unknown, but its presence in a non-degenerating tissue suggests it is not simply a consequence of neurodegeneration. We now offer confirmation of the AD platelet COX defect. Compared to age-matched controls, in mitochondria isolated from AD platelets there was a 15% decrease in COX activity despite the fact that COX subunits were present at normal levels. Platelet ATP levels were diminished in AD (from 11.33 +/- 0.52 to 9.11 +/- 0.72 nmol/mg), while reactive oxygen species (ROS) were increased (from 97.03 +/- 25.9 to 338.3 +/- 100 K/mg). Platelet membrane fluidity, Vitamin E, and cholesterol content were similar between groups. We conclude that COX catalytic activity is indeed diminished in AD platelet mitochondria, does not result from altered membrane fluidity, and is associated with ROS overproduction and ATP under-production.

Functional mitochondria are required for amyloid beta-mediated neurotoxicity

The role of mitochondria in amyloid βpeptide (Aβ)‐induced cytotoxicity is unclear. We therefore exposed NT2 cells, a clonal human teratocarcinoma cell line capable of differentiation into terminal neurons, to Aβ 25–35 or to Aβ 1–42 to evaluate cell viability and altered mitochondrial function. A 24‐h incubation of native NT2 cells (ρ+ cells) with Aβ 25–35 or with Aβ 1–42 produced a dose‐dependent decline in MTT reduction. Aβ 1–42 was shown to be more toxic compared with Aβ 25–35. Aβ 25–35 toxicity was prevented or diminished by a 22‐h preincubation with antioxidants (vitamin E, melatonin, and idebenone), as well as by simultaneous incubation with GSH or the nicotinic receptor agonist nicotine. Aβ 25–35 exposure was also associated with (1) inhibition of mitochondrial respiratory chain complexes (I, NADH‐ubiquinone oxidoreductase; II/III, succinate‐cytochrome c oxidoreductase; and IV, cytochrome c oxidase), (2) ATP depletion, and (3) reduction of the mitochondrial membrane potential. In contrast, NT2 cells rendered incapable of oxidative phosphorylation via depletion of their mitochondrial DNA (ρ0 cells) were unaffected by exposure to Aβ 25–35 or Aβ 1–42. These data indicate that Aβ can disrupt mitochondrial function and that such disruption causes oxidative stress. It is further suggested that a functional mitochondrial respiratory chain is required for Aβ toxicity.

Mitochondrial function is differentially affected upon oxidative stress

The mechanisms that lead to mitochondrial damage under oxidative stress conditions were examined in synaptosomes treated with ascorbate/iron. A loss of membrane integrity, evaluated by electron microscopy and by LDH leakage, was observed in peroxidized synaptosomes and it was prevented by pre-incubation with vitamin E (150 microM) and idebenone (50 microM). ATP levels decreased, in synaptosomes exposed to ascorbate/iron, as compared to controls. NADH-ubiquinone oxidoreductase (Cx I) and cytochrome c oxidase (Cx IV) activities were unchanged after ascorbate/iron treatment, whereas succinate-ubiquinone oxidoreductase (Cx II), ubiquinol cytochrome c reductase (Cx III) and ATP-synthase (Cx V) activities were reduced by 55%, 40%, and 55%, respectively. The decrease of complex II and ATP-synthase activities was prevented by reduced glutathione (GSH), whereas the other antioxidants tested (vitamin E and idebenone) were ineffective. However, vitamin E, idebenone and GSH prevented the reduction of complex III activity observed in synaptosomes treated with ascorbate/iron. GSH protective effect suggests that the oxidation of protein SH-groups is involved in the inhibition of complexes II, III and V activity, whereas vitamin E and idebenone protection suggests that membrane lipid peroxidation is also involved in the reduction of complex III activity. These results may indicate that the inhibition of the mitochondrial respiratory chain enzymatic complexes, that are differentially affected by oxidative stress, can be recovered by specific antioxidants.

Mitochondrial dysfunction and caspase activation in rat cortical neurons treated with cocaine or amphetamine.

Drug abuse is associated with brain dysfunction and neurodegeneration, and various recreational drugs induce apoptotic cell death. This study examined the role of the mitochondrial apoptotic pathway in psychostimulant-induced neuronal dysfunction. Using primary neuronal cultures, we observed that amphetamine (IC50=1.40 mM) was more potent than cocaine (IC50=4.30 mM) in inducing cell toxicity. Apoptotic cell death was further evaluated using cocaine and amphetamine concentrations that moderately decreased cell reduction capacity but did not affect plasma membrane integrity. Compared to cocaine, amphetamine highly decreased the mitochondrial membrane potential, as determined using the fluorescent probe rhodamine-123, whereas both drugs decreased mitochondrial cytochrome c. In contrast to amphetamine, cocaine cytotoxicity was partly mediated through effects on the electron transport chain, since cocaine toxicity was ameliorated in mitochondrial DNA-depleted cells lacking mitochondrially encoded electron transport chain subunits. Cocaine and amphetamine induced activation of caspases-2, -3 and -9 but did not affect activity of caspases-6 or -8. In addition, amphetamine, but not cocaine, was associated with the appearance of evident nuclear apoptotic morphology. These events were not accompanied by differences in the release of the apoptosis-inducing factor (AIF) from mitochondria. Our results demonstrate that although both amphetamine and cocaine activate the mitochondrial apoptotic pathway in cortical neurons, amphetamine is more likely to promote apoptosis.

Induction of cytochrome c-mediated apoptosis by amyloid β 25-35 requires functional mitochondria

Accumulating data suggest a central role for mitochondria and oxidative stress in neurodegenerative apoptosis. We previously demonstrated that amyloid-beta peptide 25-35 (Abeta 25-35) toxicity in cultured cells is mediated by its effects on functioning mitochondria. In this study, we further explored the hypothesis that Abeta 25-35 might induce apoptotic cell death by altering mitochondrial physiology. Mitochondria in Ntera2 (NT2 rho+) human teratocarcinoma cells exposed to either staurosporine (STS) or Abeta 25-35 were found to release cytochrome c, with subsequent activation of caspases 9 and 3. However, NT2 cells depleted of mitochondrial DNA (rho0 cells), which maintain a normal mitochondrial membrane potential (Deltapsi(m)) despite the absence of a functional electron transport chain (ETC), demonstrated cytochrome c release and caspase activation only with STS. We further observed increased reactive oxygen species (ROS) production and decreased reduced glutathione (GSH) levels in rho+ and rho0 cells treated with STS, but only in rho+ cells treated with Abeta 25-35. We conclude that under in vitro conditions, Abeta can induce oxidative stress and apoptosis only when a functional mitochondrial ETC is present.

Alzheimer's disease-associated neurotoxic mechanisms and neuroprotective strategies.

The characteristic hallmarks of Alzheimers disease (AD), the most common form of dementia in the elderly, include senile plaques, mainly composed of beta-amyloid (Abeta) peptide, neurofibrillary tangles and selective synaptic and neuronal loss in brain regions involved in learning and memory. Genetic studies, together with the demonstration of Abeta neurotoxicity, led to the development of the amyloid cascade hypothesis to explain the AD-associated neurodegenerative process. However, a modified version of this hypothesis has emerged, the Abeta cascade hypothesis, which takes into account the fact that soluble oligomeric forms and protofibrils of Abeta and its intraneuronal accumulation also play a key role in the pathogenesis of the disease. Recent evidence posit that synaptic dysfunction triggered by non fibrillar Abeta species is an early event involved in memory decline in AD. The current understanding of the molecular mechanisms responsible for impaired synaptic function and cognitive deficits is outlined in this review, focusing on oxidative stress and disturbed metal ion homeostasis, Ca(2+) dysregulation, mitochondria and endoplasmic reticulum dysfunction, cholesterol dyshomeostasis and impaired neurotransmission. The activation of apoptotic cell death as a mechanism of neuronal loss in AD, and the prominent role of neuroinflammation in this neurodegenerative disorder, are also reviewed herein. Furthermore, we will focus on the more relevant therapeutical strategies currently used, namely those involving antioxidants, drugs for neurotransmission improvement, hormonal replacement, gamma- and beta- secretase inhibitors, Abeta clearance agents (Abeta immunization, disruption of Abeta fibrils, modulation of the cholesterol-mediated Abeta transport), non-steroidal anti-inflammatory drugs (NSAIDs), microtubules stabilizing drugs and kinase inhibitors.

Cell degeneration induced by amyloid-β peptides

Extracellular accumulation of amyloid-beta (Abeta) peptide and death of neurons in brain regions involved in learning and memory, particularly the cortex and the hippocampus, are central features of Alzheimers disease (AD). Neuronal Ca2+ overload and apoptosis are known to occur in AD. Abeta might play a role in disrupting Ca2+ homeostasis, and this AD-associated amyloidogenic peptide has been reported to induce apoptotic death in cultured cells. However, the specific intracellular signaling pathways by which Abeta triggers cell death are not yet well defined. This article provides evidence for the involvement of mitochondrial dysfunction in Abeta-induced toxicity and for the role of mitochondria in apoptosis triggered by Abeta. In addition, the endoplasmic reticulum (ER) seems to play a role in Abeta-induced apoptotic neuronal death, the ER stress being mediated by the perturbation of ER Ca2+ homeostasis. It is likely that a better understanding of how Abeta induces neuronal apoptosis will lead to the identification of potential molecular targets for the development of therapies for AD.Extracellular accumulation of amyloid-β (Aβ) peptide and death of neurons in brain regions involved in learning and memory, particularly the cortex and the hippocampus, are central features of Alzheimer’s disease (AD). Neuronal Ca2+ overload and apoptosis are known to occur in AD. Aβ might play a role in disrupting Ca2+ homeostasis, and this AD-associated amyloidogenic peptide has been reported to induce apoptotic death in cultured cells. However, the specific intracellular signaling pathways by which Aβ triggers cell death are not yet well defined. This article provides evidence for the involvement of mitochondrial dysfunction in Aβ-induced toxicity and for the role of mitochondria in apoptotsis triggered by Aβ. In addition, the endoplasmic reticulum (ER) seems to play a role in Aβ-induced apoptotic neuronal death, the ER stress being mediated by the perturbation of ER Ca2+ homeostasis. It is likely that a better understanding of how Aβ induces neuronal apoptosis will lead to the identification of potential molecular targets for the development of therapies for AD.

Mitochondrial function in Parkinson’s disease cybrids containing an nt2 neuron-like nuclear background

Mitochondria likely play a role in Parkinsons disease (PD) neurodegeneration. We modelled PD by creating cytoplasmic hybrid (cybrid) cell lines in which endogenous mitochondrial DNA (mtDNA) from PD or control subject platelets was expressed within human teratocarcinoma (NT2) cells previously depleted of endogenous mtDNA. Complex I activity was reduced in both PD cybrid lines and in the platelet mitochondria used to generate them. Under basal conditions PD cybrids had less ATP, more LDH release, depolarized mitochondria, less mitochondrial cytochrome c, and higher caspase 3 activity. Equivalent MPP+ exposures are more likely to trigger programmed cell death in PD cybrid cells than in control cybrid cells. Our data support a relatively upstream role for mitochondrial dysfunction in idiopathic PD.