Brain cortex mitochondrial bioenergetics in synaptosomes and non-synaptic mitochondria during aging

Lores‐Arnaiz, Silvia; Lombardi, Paula E.; Karadayian, Analía G.; Orgambide, Federico; Cicerchia, Daniela; Bustamante, Juanita

doi:10.1007/s11064-015-1817-5

Cited by 59 publications

(34 citation statements)

References 41 publications

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“…Nevertheless, it is important to note that while respirometry measures how much oxygen is consumed, this design does not describe the fate of that oxygen, and whether it contributes to ATP or ROS production. We therefore assessed the efficiency of the electron transport chain in mitochondrial isolates from the SVCT2 +/− and the APP/PSEN1 mice by measuring mitochondrial membrane potential and ATP/ADP ratios to identify individual contributions of each mutation [21,51,59]. We used dihydrofluorescein to measure of ROS production given that disruption of the electron transport chain leads to oxidative stress.…”

Section: Resultsmentioning

confidence: 99%

“…Freshly isolated cortical mitochondria were assayed at 0.5mg protein/ml MiR05 respiration buffer to a final volume of 2mL per chamber in an O2K Oxygraph (Oroboros, Innsbruck, Austria). Baseline oxygen uptake was established over 10 minutes and oxygen flux was measured and normalized to protein concentration under State 4 respiration in the presence of glutamate (10mM), and malate (2mM) and State 3 respiration was determined by the addition of ADP (2mM) [49–51] over a 10-minute time-span for each. We calculated a “pseudo” respiratory control ratio by normalizing oxygen consumed by isolated mitochondria after the addition of ADP (State 3) to the oxygen consumed at baseline in the absence of substrate or inhibitor (State 4).…”

Section: Methodsmentioning

confidence: 99%

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Mitochondrial dysfunction in the APP/PSEN1 mouse model of Alzheimer’s disease and a novel protective role for ascorbate

Dixit

Fessel

Harrison

2017

Free Radical Biology and Medicine

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Mitochondrial dysfunction is elevated in very early stages of Alzheimer’s disease and exacerbates oxidative stress, which contributes to disease pathology. Mitochondria were isolated from 4-month-old wild-type mice, transgenic mice carrying the APPSWE and PSEN1dE9 mutations, mice with decreased brain and mitochondrial ascorbate (vitamin C) via heterozygous knockout of the sodium dependent vitamin C transporter (SVCT2+/−) and transgenic APP/PSEN1 mice with heterozygous SVCT2 expression. Mitochondrial isolates from SVCT2+/− mice were observed to consume less oxygen using high-resolution respirometry, and also exhibited decreased mitochondrial membrane potential compared to wild type isolates. Conversely, isolates from young (4 months) APP/PSEN1 mice consumed more oxygen, and exhibited an increase in mitochondrial membrane potential, but had a significantly lower ATP/ADP ratio compared to wild type isolates. Greater levels of reactive oxygen species were also produced in mitochondria isolated from both APP/PSEN1 and SVCT2+/− mice compared to wild type isolates. Acute administration of ascorbate to mitochondria isolated from wild-type mice increased oxygen consumption compared with untreated mitochondria suggesting ascorbate may support energy production. This study suggests that both presence of amyloid and ascorbate deficiency can contribute to mitochondrial dysfunction, even at an early, prodromal stage of Alzheimer’s disease, although occurring via different pathways. Ascorbate may, therefore, provide a useful preventative strategy against neurodegenerative disease, particularly in populations most at risk for Alzheimer’s disease in which stores are often depleted through mitochondrial dysfunction and elevated oxidative stress.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Mitochondrial dysfunction in the APP/PSEN1 mouse model of Alzheimer’s disease and a novel protective role for ascorbate

Dixit

Fessel

Harrison

2017

Free Radical Biology and Medicine

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“…They include analysis of mitochondria-specific proteins, functional interrogation of isolated mitochondria or mitochondria in synaptosome preparations, and manipulation of genes that encode mitochondrial proteins (Grimm and Eckert, 2017). Comparisons of mitochondria isolated from brain tissue of animals reveal numerous age-related alterations, including mitochondrial enlargement or fragmentation (Stahon et al, 2016; Morozov et al, 2017), increased oxidative damage to mitochondrial DNA (Kim and Chan, 2001; Santos et al, 2013), impaired function of the electron transport chain (ETC) (Yao et al, 2010; Pandya et al, 2015, 2016; Pollard et al, 2016), increased numbers of mitochondria with depolarized membranes (Lores-Arnaiz et al, 2016), impaired Ca 2+ handling (Leslie et al, 1985; Pandya et al, 2015), and a reduced threshold for triggering mPTP formation (Brown et al, 2004). The decrement in mitochondrial function during brain aging involves a decline in cellular NAD + levels and the NAD:NADH ratio (Braidy et al, 2014), which would be expected to compromise the activities of NAD + -dependent enzymes critical for neuronal function and viability, including protein deacetylases of the sirtuin family (Fang et al, 2017).…”

Section: Cellular and Molecular Hallmarks Of Brain Agingmentioning

confidence: 99%

Hallmarks of Brain Aging: Adaptive and Pathological Modification by Metabolic States

2018

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During aging, the cellular milieu of the brain exhibits tell-tale signs of compromised bioenergetics, impaired adaptive neuroplasticity and resilience, aberrant neuronal network activity, dysregulation of neuronal Ca2+ homeostasis, the accrual of oxidatively modified molecules and organelles, and inflammation. These alterations render the aging brain vulnerable to Alzheimer’s and Parkinson’s diseases and stroke. Emerging findings are revealing mechanisms by which sedentary overindulgent lifestyles accelerate brain aging, whereas lifestyles that include intermittent bioenergetic challenges (exercise, fasting, and intellectual challenges) foster healthy brain aging. Here we provide an overview of the cellular and molecular biology of brain aging, how those processes interface with disease-specific neurodegenerative pathways, and how metabolic states influence brain health.

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“…Mather & Rottenberg, ), different types of cells from the same tissue (cf. LaFrance et al ., ; Bambrick et al ., ; Picard et al ., ; Lores‐Arnaiz et al ., ), and even between mitochondria from different locations in the cell (Brown et al ., ). This variability probably results from the large differences in the expression and activity of the proteins that control activation of the mPTP such as ANT1 (Stepien et al ., ), CyPD (Hazelton et al ., ), the MCU complex (Paillard et al ., ), and probably other proteins.…”

Section: Mptp Activation Is Enhanced By Aging and In Aging‐dependent mentioning

confidence: 99%

The path from mitochondrial ROS to aging runs through the mitochondrial permeability transition pore

Rottenberg¹,

2017

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SummaryExcessive production of mitochondrial reactive oxygen species (mROS) is strongly associated with mitochondrial and cellular oxidative damage, aging, and degenerative diseases. However, mROS also induces pathways of protection of mitochondria that slow aging, inhibit cell death, and increase lifespan. Recent studies show that the activation of the mitochondrial permeability transition pore (mPTP), which is triggered by mROS and mitochondrial calcium overloading, is enhanced in aged animals and humans and in aging‐related degenerative diseases. mPTP opening initiates further production and release of mROS that damage both mitochondrial and nuclear DNA, proteins, and phospholipids, and also releases matrix NAD that is hydrolyzed in the intermembrane space, thus contributing to the depletion of cellular NAD that accelerates aging. Oxidative damage to calcium transporters leads to calcium overload and more frequent opening of mPTP. Because aging enhances the opening of the mPTP and mPTP opening accelerates aging, we suggest that mPTP opening drives the progression of aging. Activation of the mPTP is regulated, directly and indirectly, not only by the mitochondrial protection pathways that are induced by mROS, but also by pro‐apoptotic signals that are induced by DNA damage. We suggest that the integration of these contrasting signals by the mPTP largely determines the rate of cell aging and the initiation of cell death, and thus animal lifespan. The suggestion that the control of mPTP activation is critical for the progression of aging can explain the conflicting and confusing evidence regarding the beneficial and deleterious effects of mROS on health and lifespan.

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Brain cortex mitochondrial bioenergetics in synaptosomes and non-synaptic mitochondria during aging

Cited by 59 publications

References 41 publications

Mitochondrial dysfunction in the APP/PSEN1 mouse model of Alzheimer’s disease and a novel protective role for ascorbate

Mitochondrial dysfunction in the APP/PSEN1 mouse model of Alzheimer’s disease and a novel protective role for ascorbate

Hallmarks of Brain Aging: Adaptive and Pathological Modification by Metabolic States

The path from mitochondrial ROS to aging runs through the mitochondrial permeability transition pore

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