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We have investigated the extent to which functional expression of the plant alternative oxidase (from Sauromatum guttatum) in Schizosaccharomyces pombe affects yeast growth. When cells are cultured on glycerol, the maximum specific growth rate is decreased from 0.13 to 0.11 h-1 while growth yield is lowered by 20% (from 1. 14 x 10(8) to 9.12 x 10(7) cells ml-1). Kinetic studies suggest that the effect on growth is mitochondrial in origin. In isolated mitochondria we found that the alternative oxidase actively competes with the cytochrome pathway for reducing equivalents and contributes up to 24% to the overall respiratory activity. Metabolic control analysis reveals that the alternative oxidase exerts a considerable degree of control (22%) on total electron flux. Furthermore, the negative control exerted by the alternative oxidase on the flux ratio of electrons through the cytochrome and alternative pathways is comparable with the positive control exerted on this flux-ratio by the cytochrome pathway. To our knowledge, this is the first paper to report a phenotypic effect because of plant alternative oxidase expression. We suggest that the effect on growth is the result of high engagement of the non-protonmotive alternative oxidase in yeast respiration that, consequently, lowers the efficiency of energy conservation and hence growth.  +

We have investigated the extent to which functional expression of the plant alternative oxidase (from ''Sauromatum guttatum'') in ''Schizosaccharomyces pombe'' affects yeast growth. When cells are cultured on glycerol, the maximum specific growth rate is decreased from 0.13 to 0.11 h^-1 while growth yield is lowered by 20% (from 1. 14 x 10⁸ to 9.12 x 10⁷ cells ml^-1). Kinetic studies suggest that the effect on growth is mitochondrial in origin. In isolated mitochondria we found that the alternative oxidase actively competes with the cytochrome pathway for reducing equivalents and contributes up to 24% to the overall respiratory activity. Metabolic control analysis reveals that the alternative oxidase exerts a considerable degree of control (22%) on total electron flux. Furthermore, the negative control exerted by the alternative oxidase on the flux ratio of electrons through the cytochrome and alternative pathways is comparable with the positive control exerted on this flux-ratio by the cytochrome pathway. To our knowledge, this is the first paper to report a phenotypic effect because of plant alternative oxidase expression. We suggest that the effect on growth is the result of high engagement of the non-protonmotive alternative oxidase in yeast respiration that, consequently, lowers the efficiency of energy conservation and hence growth.  +

Regulation of succinate dehydrogenase was investigated using tightly coupled potato tuber mitochondria in a novel fashion by simultaneously measuring the oxygen uptake rate and the ubiquinone (Q) reduction level. We found that the activation level of the enzyme is unambiguously reflected by the kinetic dependence of the succinate oxidation rate upon the Q-redox poise. Kinetic results indicated that succinate dehydrogenase is activated by both ATP (K_1/2) approximately 3 microm) and ADP. The carboxyatractyloside insensitivity of these stimulatory effects indicated that they occur at the cytoplasmic side of the mitochondrial inner membrane. Importantly, our novel approach revealed that the enzyme is also activated by oligomycin (K_1/2) approximately 16 nm). Time-resolved kinetic measurements of succinate dehydrogenase activation by succinate furthermore revealed that the activity of the enzyme is negatively affected by potassium. The succinate-induced activation (+/-K⁺) is prevented by the presence of an uncoupler. Together these results demonstrate that ''in vitro'' activity of succinate dehydrogenase is modulated by the protonmotive force. We speculate that the widely recognized activation of the enzyme by adenine nucleotides in plants is mediated in this manner. A mechanism that could account for such regulation is suggested and ramifications for its ''in vivo'' relevance are discussed.  +

Oxidative phosphorylation is an important energy-conserving mechanism coupling mitochondrial electron transfer to ATP synthesis. Coupling between respiration and phosphorylation is not fully efficient due to proton and electron leaks. In this chapter, methods are presented to measure proton and electron leak activities in isolated mitochondria. The relative strength of a modular kinetic approach to probe oxidative phosphorylation is emphasised.  +

The studies aimed at determine the effect of body mass index (BMI) on aerobic power (VO2max) and energy expenditure (EE) during manual operation in primary agro-processing. Selected physiological and anthropometry properties of voluntary group of thirteen subjects were measured with respect to manual lifting of loads through the vertical distance of 0.92m from ankle level to inlet opening of thresher during threshing operation. The measured properties showed that height and weight ranged from 1.65m to 1.83m and 53g to 78g respectively, the calculated BMI ranged from 18.38kg/m2 to 28.65kg/m2. Heart rate at rest (HRrest) and maximum heart rate (HRmax) were measured with maximum; minimum values of 56beat/min; 89beat/min and 191beat/min; 200beat/min corresponded to mean ± SD of 72.5 ± 11.7 and 195.8 ± 3.0 respectively. The calculated EE and VO2max have minimum; maximum values of 94kj/min; 396kj/min and 32.2ml/min/kg; 52.5ml/min/kg corresponded to mean ± SD of 238.7 ± 92.5 and 41.5 ± 6.9. Results on relational effects showed that increase in EE relate positively to BMI, while increase in VO2max relate negatively to BMI. Also, it was found that heights of the subjects relate directly to lifted loads, while body weights relate inversely to the lifted loads. Regression models that could be used to express the relationship existing between independent variables EE (e) and VO2max (a), and dependent variable BMI (yB) are; yB = 6.2792e + 106.9 (R2 = 0.0361) and yB = - 0.4858 a + 51.689 (R2 = 0.039) respectively. Also, the regression models for relationship that occurred between independent variables height (h) and weight (w) and dependent variable load quantity (yL)are; yL= 0.2465h +164.58 (R2 = 0.091) and yL = -0 .4018w +78.592 (R2 = 0.1389)respectively. Environmental conditions such as relative humidity, air temperature and atmospheric pressure were noted, and has the values of 84.57%, 21.79oC and 765mmHg respectively. The relationship existing between the physiological factors and BMI were found to be adequately expressed by regression equations.  

[[Image:MITOEAGLE-logo.jpg|left|100px|link=http://www.mitoglobal.org/index.php/MITOEAGLE|COST Action MitoEAGLE]] Mitochondria have significant impact on the suppleness for cancer cell proliferation and survival in stress environments, for example, nutrient diminution, hypoxia, and during cancer treatments. Mitochondria are the most important supply of reactive oxygen species (ROS), which are taken part in a vital role in mitochondria mediated apoptosis and mitochondrial aerobic respiration [1]. Moreover, in energy stress condition, AMPK activation aggravates cell survival via redox regulation for overcoming the metabolic stress [2]. Thus, the aim of the present study was to investigate the chemopreventive effects of Manuka honey (MH) by targeting mitochondrial dysfunction, while mitochondria play as an important mediator of tumorigenesis. MH is a good source of natural bioactive compounds and antioxidant capacity [3]. Human colon cancer Lovo cells were cultured in the presence of MH at different concentrations (0 to 50 mg/ mL) for up to 72 h and the cell viability percentage was evaluated by MTT assay. Tali® image based Cytometer was used for evaluating the ROS production and apoptosis rate. Seahorse Bioscience XF24 Extracellular Flux Analyzer was used for detection of oxygen consumption rate (OCR) as an indicator of mitochondrial oxidative phosphorylation by sequential adding of oligomycin, 2,4-DNP and rotenone/ antimycin and extracellular acidification rate (ECAR) as an indicator of glycolysis by adding rotenone, glucose and 2-DG. The sensitive measurement of glycolysis and several parameters of mitochondrial function from adherent intact cultured cells were measured. Western blotting analysis was performed for detection of the protein expression of p53, caspase-3 and AMPK pathway. MH suppressed the LoVo cells proliferation at dose and time dependent manner. It increased the intracellular ROS production and apoptotic rate of the LoVo cells, while the expression of apoptosis inducer, p53 and caspase-3 also increased after MH treatment. Seahorse analysis showed that MH markedly decreased mitochondrial function by reducing oxidative phosphorylation as an indicator of OCR (Figure 1A). The basal respiration, maximal oxygen consumption, spare respiratory capacity, ATP-linked respiration and proton leak, associated with cell survival, were also decreased after MH treatment compared to control (Figure 1B). In addition, it reduced the glycolysis function and suppressed the AMPK pathway expression as a consequence; it inhibited the production of ATP under metabolic stress. Our result suggested that mitochondrial dysfunction is one of the prime therapeutic tenures, while MH is a possible elevator of ROS production in order to activated apoptosis and disturbed bioenergetics phenotype of colon cancer cells may contribute to preclinical and clinical appraisal for cancer therapy.  

The present study investigated the effects of orally administered long chain omega-3 polyunsaturated fatty acids (PUFA) on mitochondrial function and processing of the amyloid precursor protein (APP) in brains of young (3 months old) and aged (24 months old) NMRI-mice. Neuroprotective properties of fish oil (FO) (1.6ml/kg p.o.) were assessed ex vivo after 21 days in dissociated brain cells (DBC) and isolated mitochondria. Docosahexaenoic acid (DHA) levels were significantly lower in blood and brains of aged mice which were compensated by FO administration. Isolated DBC and mitochondria from aged mice showed significantly lower adenosine triphosphate (ATP) levels and reduced activity of complexes I+II and IV of the mitochondrial respiration system, respectively. FO restored the age-related decrease in respiration and improved ATP production. Moreover, FO increased the levels of anti-apoptotic Bcl-2 protein. Cell membrane fractions isolated from the brain of aged mice exhibited lower membrane fluidity, which was partially improved under FO treatment. In comparison to young animals, levels of neuroprotective sAPPα were significantly lower in the brain of aged mice. However, levels of sAPPα, Aβ and C-terminal APP fragments (CTF) were largely unchanged after FO treatment in aged mice. Neuroprotectin D-1 (NPD-1) represents a neuroprotective compound that is derived from unesterified DHA. Levels of NPD1-like metabolites (NPD1-like) and of unesterified DHA were significantly increased in brains of aged mice. FO treatment further strongly increased NPD1-like levels indicating an accelerated conversion rate of free DHA to NPD1-like. Our findings provide new mechanisms underlying the neuroprotective actions of omega-3 PUFA and identified FO as a promising nutraceutical to delay age-related mitochondrial dysfunction in the brain.  +

The Prevención con Dieta Mediterránea (PREDIMED) trial1 is one of the most influential randomised trials ever. It was cited 3364 times in Google Scholar in the five years after its publication. However, in June 2018 the trial was retracted and republished because serious protocol deviations were detected. Moreover, the repercussions of these protocol deviations and of the correction process raise many additional important questions. How do you correct one of the most influential trials and the large universe of its secondary publications?  +

Hepatic mitochondrial dysfunction is thought to play a role in the development of liver steatosis and insulin resistance, which are both common characteristics of obesity and type 2 diabetes mellitus (T2DM). It was hypothesized that the antioxidant properties of melatonin could potentially improve the impaired functions of hepatic mitochondria in diabetic obese animals. Male Zucker diabetic fatty (ZDF) rats and lean littermates (ZL) were given either melatonin (10 mg/kg BW/day) orally for 6 wk (M-ZDF and M-ZL) or vehicle as control groups (C-ZDF and C-ZL). Hepatic function was evaluated by measurement of serum alanine transaminase and aspartate transaminase levels, liver histopathology and electron microscopy, and hepatic mitochondrial functions. Several impaired functions of hepatic mitochondria were observed in C-ZDF in comparison with C-ZL rats. Melatonin treatment to ZDF rats decreases serum levels of ALT (''P'' < 0.001), alleviates liver steatosis and vacuolation, and also mitigates diabetic-induced mitochondrial abnormalities, glycogen, and lipid accumulation. Melatonin improves mitochondrial dysfunction in M-ZDF rats by increasing activities of mitochondrial citrate synthase (''P'' < 0.001) and complex IV of electron transfer chain (''P'' < 0.05) and enhances state 3 respiration (''P'' < 0.001), respiratory control index (RCR) (''P'' < 0.01), and phosphorylation coefficient (ADP/O ratio) (''P'' < 0.05). Also melatonin augments ATP production (''P'' < 0.05) and diminishes uncoupling protein 2 levels (''P'' < 0.001). These results demonstrate that chronic oral melatonin reduces liver steatosis and mitochondria dysfunction in ZDF rats. Therefore, it may be beneficial in the treatment of diabesity.  +

Obesity and associated diabetes (diabesity) impair kidney mitochondrial dynamics by augmenting fission and diminishing fusion, which results in mitochondrial and renal dysfunction. Based on available evidence, the antioxidant activities of melatonin may improve impaired renal mitochondrial function in obese diabetic animals by restoring the imbalanced dynamics through inhibiting fission and promoting fusion. Male Zücker diabetic fatty (ZDF) rats and lean littermates (ZL) were orally treated either with melatonin (10 mg/kg BW/day) (M-ZDF and M-ZL) or vehicle (C-ZDF and C-ZL) for 17 weeks. Kidney function was evaluated by measurement of total urine volume, proteinuria, creatinine clearance, and assessment of kidney mitochondrial dynamics and function. C-ZDF exhibited impaired dynamics and function of kidney mitochondria in comparison to C-ZL. Melatonin improved nephropathy of ZDF rats and modulated their mitochondrial dynamics by reducing expression of Drp1 fission marker and increasing that of fusion markers, Mfn2 and Opa1. Furthermore, melatonin ameliorated mitochondrial dysfunction by increasing respiratory control index and electron transfer chain complex IV activity. In addition, it lowered mitochondrial oxidative status. Our findings show that melatonin supplementation improves nephropathy likely via modulation of the mitochondrial fission/fusion balance and function in ZDF rats.  +

The racemates of substituted 2-oxiranecarboxylates are potent inhibitors of fatty acid oxidation and fatty acid and cholesterol synthesis. We show in the accompanying paper [Agius L, Peak M and Sherratt HSA, Biochem Pharmacol 42: 1711-1715, 1991] that only the R-enantiomer of etomoxir, a potent hypoglycaemic compound, inhibits fatty acid oxidation in hepatocytes. We demonstrate in this paper that although the R-enantiomer of etomoxir is esterified to its CoA-ester more readily than the S-enantiomer, both the R- and S-enantiomers are equally potent inhibitors of fatty acid and cholesterol synthesis from acetate in rat hepatocytes. The inhibition of fatty acid synthesis is not due to direct inhibition of fatty acid synthetase and the inhibition of cholesterol synthesis occurs at a site proximal to formation of mevalonate. Since the S-enantiomer inhibits fatty acid and cholesterol synthesis but not fatty acid oxidation the inhibition of the biosynthetic pathways is not coupled to inhibition of fatty acid oxidation.  +

Background: Humans and non-human animals share an approximate non-verbal system for representing and comparing numerosities that has no upper limit and for which accuracy is dependent on the numerical ratio. Current evidence indicates that the mechanism for keeping track of individual objects can also be used for numerical purposes; if so, its accuracy will be independent of numerical ratio, but its capacity is limited to the number of items that can be tracked, about four. There is, however, growing controversy as to whether two separate number systems are present in other vertebrate species. Methodology/Principal Findings: In this study, we compared the ability of undergraduate students and guppies to discriminate the same numerical ratios, both within and beyond the small number range. In both students and fish the performance was ratio-independent for the numbers 1–4, while it steadily increased with numerical distance when larger numbers were presented. Conclusions/Significance: Our results suggest that two distinct systems underlie quantity discrimination in both humans and fish, implying that the building blocks of uniquely human mathematical abilities may be evolutionarily ancient, dating back to before the divergence of bony fish and tetrapod lineages.  +

Although the decrease of pyruvate secretion by brewer’s yeasts during fermentation has long been desired in the alcohol beverage industry, rather little is known about the regulation of pyruvate accumulation. In this study, we have characterized a previously developed a pyruvate undersecreting sake yeast obtained by isolating a strain (TCR7) tolerant to ethyl α-transcyanocinnamate, an inhibitor of pyruvate transport into mitochondria. To obtain insights into pyruvate metabolism, we investigated the mitochondrial activity of TCR7 by oxigraphy and 13C-metabolic flux analysis during aerobic growth . While mitochondrial pyruvate oxidation was higher, glycerol production was decreased in TCR7 compared to the reference. These results indicate that mitochondrial activity is elevated in the TCR7 strain with the consequence of decreased pyruvate accumulation. Surprisingly mitochondrial activity is much higher in the sake yeast compared to CEN.PK 113-7D, the reference strain in metabolic engineering. When shifted from aerobic to anaerobic conditions, sake yeast retains a branched mitochondrial structure for a longer time than laboratory strains. The regulation of mitochondrial activity can become a completely novel approach to manipulate metabolic profile during fermentation of brewer’s yeasts. [[File:Abstract Agrimi G Graphical.jpg|center|450px]]  +

Depression is a debilitating condition with a profound impact on quality of life for millions of people worldwide. Physical exercise is used as a treatment strategy for many patients, but the mechanisms that underlie its beneficial effects remain unknown. Here, we describe a mechanism by which skeletal muscle PGC-1α1 induced by exercise training changes kynurenine metabolism and protects from stress-induced depression. Activation of the PGC-1α1-PPARα/δ pathway increases skeletal muscle expression of kynurenine aminotransferases, thus enhancing the conversion of kynurenine into kynurenic acid, a metabolite unable to cross the blood-brain barrier. Reducing plasma kynurenine protects the brain from stress-induced changes associated with depression and renders skeletal muscle-specific PGC-1α1 transgenic mice resistant to depression induced by chronic mild stress or direct kynurenine administration. This study opens therapeutic avenues for the treatment of depression by targeting the PGC-1α1-PPAR axis in skeletal muscle, without the need to cross the blood-brain barrier.  +

Immunodetection of protein carbonyl groups demonstrates that growth arrest elicited by carbon or nitrogen starvation causes an increased oxidation of proteins in ''Saccharomyces cerevisiae''. Mutant analysis suggests that the response regulator Pos9p is involved in mitigating self-inflicted oxidative damages in G0 cells, whereas Yap1p is primarily required in growing cells. The data also suggest that oxidation of target proteins is not a'' priori'' an effect of arrest of cell division or nutrient depletion and cannot be explained by the respiratory activity alone nor a high ratio of catabolic/anabolic activity in G0 cells. Instead, we observed that starvation elicits a transition in the respiratory state (from phosphorylating to nonphosphorylating respiration) and that this transition is associated with a stepwise increase in protein oxidation. During carbon starvation, this transition and increase in oxidation occurs immediately as the carbon source is depleted, growth is arrested, and the respiratory rate falls drastically. In contrast, during nitrogen starvation and excess carbon the respiratory state transition and stepwise increase in protein oxidation are markedly delayed and occur long after the nitrogen source has been depleted and division and growth-arrested. Oxidation in G0 cells could be enhanced by treating cells with low concentrations of antimycin A and attenuated with myxothiazol, indicating that protein oxidation is intimately linked to reactive oxygen species generated by semiquinones of the Q-cycle. Thus, the work presented suggests that the degree of coupling in the mitochondrial respiratory apparatus rather then the overall rate of respiration affects the degree of protein oxidation in nondividing yeast cells.  +

Colorectal cancer (CRC) is associated with metabolic and redox perturbation. The mitochondrial transporter uncoupling protein 2 (UCP2) controls cell proliferation ''in vitro'' through the modulation of cellular metabolism, but the underlying mechanism in tumors ''in vivo'' remains unexplored. Using murine intestinal cancer models and CRC patient samples, we find higher UCP2 protein levels in tumors compared to their non-tumoral counterparts. We reveal the tumor-suppressive role of UCP2 as its deletion enhances colon and small intestinal tumorigenesis in AOM/DSS-treated and Apc^Min/+ mice, respectively, and correlates with poor survival in the latter model. Mechanistically, UCP2 loss increases levels of oxidized glutathione and proteins in tumors. UCP2 deficiency alters glycolytic pathways while promoting phospholipid synthesis, thereby limiting the availability of NADPH for buffering oxidative stress. We show that UCP2 loss renders colon cells more prone to malignant transformation through metabolic reprogramming and perturbation of redox homeostasis and could favor worse outcomes in CRC. <small>Copyright © 2019 The Authors. Published by Elsevier Inc. All rights reserved.</small>  +

Nitric oxide (NO) inhibits mitochondrial respiration by decreasing the apparent affinity of cytochrome c oxidase (CIV) for oxygen. Using iNOS-transfected HEK 293 cells to achieve regulated intracellular NO production, we determined NO and O₂ concentrations and mitochondrial O₂ consumption by high-resolution respirometry over a range of O₂ concentrations down to nanomolar. Inhibition of respiration by NO was reversible, and complete NO removal recovered cell respiration above its routine reference values. Respiration was observed even at high NO concentrations, and the dependence of IC₅₀ on [O₂] exhibits a characteristic but puzzling parabolic shape; both these features imply that CIV is protected from complete inactivation by NO and are likely to be physiologically relevant. We present a kinetic model of CIV inhibition by NO that efficiently predicts experimentally determined respiration at physiological O₂ and NO concentrations and under hypoxia, and accurately predicts the respiratory responses under hyperoxia. The model invokes competitive and uncompetitive inhibition by binding of NO to the reduced and oxidized forms of CIV, respectively, and suggests that dissociation of NO from reduced CIV may involve its O₂ dependent oxidation. It also explains the non-linear dependence of IC₅₀ on O₂ concentration, and the hyperbolic increase of ''c''₅₀ as a function of NO concentration.  +

The possible existence of a mitochondrially localized nitric oxide (NO) synthase (mtNOS) is controversial. To clarify this, we studied the ability of intact mitochondria to generate NO and the effect of mitochondrial NO on respiration. Respiratory rates and oxygen kinetics (P(50) values) were determined by high-resolution respirometry in skeletal-muscle mitochondria from control mice and mice injected with Escherichia coli lipopolysaccharide (LPS). In the presence of the NOS substrate L-arginine, mitochondria from LPS-treated mice had lower respiration rates and higher P(50) values than control animals. These effects were prevented by the NOS inhibitor L-NMMA. Our results suggest that mitochondrially derived NO is generated by an LPS-inducible NOS protein other than iNOS and modulates oxygen consumption in mouse skeletal muscle.  +

About two decades ago, West and coworkers established a model which predicts that metabolic rate follows a three quarter power relationship with the mass of an organism, based on the premise that tissues are supplied nutrients through a fractal distribution network. Quarter power scaling is widely considered a universal law of biology and it is generally accepted that were in-vitro cultures to obey allometric metabolic scaling, they would have more predictive potential and could, for instance, provide a viable substitute for animals in research. This paper outlines a theoretical and computational framework for establishing quarter power scaling in three-dimensional spherical constructs in-vitro, starting where fractal distribution ends. Allometric scaling in non-vascular spherical tissue constructs was assessed using models of Michaelis Menten oxygen consumption and diffusion. The models demonstrate that physiological scaling is maintained when about 5 to 60% of the construct is exposed to oxygen concentrations less than the Michaelis Menten constant, with a significant concentration gradient in the sphere. The results have important implications for the design of downscaled in-vitro systems with physiological relevance.  +

Reactive oxygen species (ROS) are highly reactive molecules that are generated from oxygen metabolism. They can be free radicals or non-radicals. Free radicals are molecules that contain at least one unpaired valence electron at their outer shell, making them highly reactive and short lived [1]. Among all the ROS, superoxide anion (•O2 −), hydrogen peroxide (H2O2) and hydroxyl radicals (•OH) are the most known examples. Reactive nitrogen species (RNS), is the subclass of ROS that contain nitrogen compound [2]. Both ROS and RNS, when present in physiological amount, have important roles in normal cellular functions such as fighting against infection, regulating different intercellular signaling pathways and facilitating normal maturation and fertilization in reproductive systems [1, 3–7]. However, when ROS present in high concentration, overwhelming the antioxidant defense system, oxidative stress results, and this may lead to cellular dysfunction via lipid peroxidation, protein and DNA damages [8]. Due to such damaging effect on the cells, OS is related to many pathological conditions including infertility [3, 9].  +

The electron transport chain is a series of four protein complexes that couple redox reactions, creating an electrochemical gradient that leads to the creation of ATP in a complete system named oxidative phosphorylation. It occurs in mitochondria in both cellular respiration and photosynthesis. In the former, the electrons come from breaking down organic molecules, and energy is released. In the latter, the electrons enter the chain after being excited by light, and the energy released is used to build carbohydrates.  +

The effects of an avocado-derived fatty acid oxidation (FAO) inhibitor, avocatin B (AvoB), on glucose and lipid metabolism in models of diet-induced obesity (DIO) and ''in vitro'' models of lipotoxicity are evaluated. The safety of its oral consumption in humans is also determined. Mice are given high-fat diets (HFD) for 8 weeks. Thereafter, AvoB or vehicle is administered orally twice weekly for 5 weeks. AvoB inhibits FAO which led to improved glucose tolerance, glucose utilization, and insulin sensitivity. AvoB's effects on metabolism under lipotoxic conditions are evaluated in vitro in pancreatic β-islet cells and C2C12 myotubes. AvoB inhibits FAO and increases glucose oxidation, resulting in lowering of mitochondrial reactive oxygen species that improves insulin responsiveness in C2C12 myotubes and insulin secretion in INS-1 (832/13) cells, respectively. A randomized, double-blind, placebo-controlled clinical trial in healthy human participants is conducted to assess the safety of AvoB consumption (50 mg or 200 mg per day for 60 days). AvoB is well-tolerated and not associated with any dose-limiting toxicity. Therapeutic agents that are safe and effectively inhibit FAO and improve DIO-associated pathologies are currently not available. AvoB's mechanism of action and favorable safety profile highlight its nutritional and clinical importance. <small>© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.</small>  +

'''Background''': Atherosclerosis is one of the major complications of diabetes, which may result from insulin resistance via mitochondrial dysfunction. Although a strong association between insulin resistance and cardiovascular disease has been suggested, it is not clear yet whether stress-inducing factors damage mitochondria and insulin signaling pathway in cardiovascular tissues. '''Methods''': We investigated whether stress-induced mitochondrial dysfunction might alter the insulin/Akt signaling pathway in A10 rat vascular smooth muscle cells (VSMC). '''Results''': The treatment of oxidized low density lipoprotein (oxLDL) decreased ATP contents, mitochondrial respiration activity, mRNA expressions of OXPHOS subunits and IRS-1/2 and insulin-mediated phosphorylations of Akt and AMP-activated protein kinase (AMPK). Similarly, dideoxycytidine (ddC), the mtDNA replication inhibitor, or rotenone, OXPHOS complex I inhibitor, inhibited the insulin-mediated pAkt while increased pAMPK regardless of insulin. Reciprocally, an inhibitor of Akt, triciribine (TCN), decreased cellular ATP contents. Overexpression of Akt dominant positive reversed the oxLDL- or ddC-mediated ATP decrease but AMPK activator did not. Akt activation also normalized the aberrant VSMC migration induced by ddC. '''Conclusions''': Defective insulin signaling and mitochondrial function may collectively contribute to developing cardiovascular disease. '''General significance''': Akt may be a possible therapeutic target for treating insulin resistance-associated atherosclerosis.  +

Age-related loss of skeletal muscle mass and contractile dysfunction, or sarcopenia, reduces independence and quality of life in the elderly and leads to increased risk of comorbidities...  +

Excess reactive oxygen species (ROS) and muscle weakness occur in parallel in multiple pathological conditions. However, the causative role of skeletal muscle mitochondrial ROS (mtROS) on neuromuscular junction (NMJ) morphology and function and muscle weakness has not been directly investigated. We generated mice lacking skeletal muscle-specific manganese-superoxide dismutase (mSod2KO) to increase mtROS using a cre-Lox approach driven by human skeletal actin. We determined primary functional parameters of skeletal muscle mitochondrial function (respiration, ROS, and calcium retention capacity) using permeabilized muscle fibers and isolated muscle mitochondria. We assessed contractile properties of isolated skeletal muscle using ''in situ'' and ''in vitro'' preparations and whole lumbrical muscles to elucidate the mechanisms of contractile dysfunction. The mSod2KO mice, contrary to our prediction, exhibit a 10-15% increase in muscle mass associated with an ~50% increase in central nuclei and ~35% increase in branched fibers (P < 0.05). Despite the increase in muscle mass of ''gastrocnemius'' and ''quadriceps'', in situ sciatic nerve-stimulated isometric maximum-specific force (N/cm²), force per cross-sectional area, is impaired by ~60% and associated with increased NMJ fragmentation and size by ~40% (P < 0.05). Intrinsic alterations of components of the contractile machinery show elevated markers of oxidative stress, for example, lipid peroxidation is increased by ~100%, oxidized glutathione is elevated by ~50%, and oxidative modifications of myofibrillar proteins are increased by ~30% (P < 0.05). We also find an approximate 20% decrease in the intracellular calcium transient that is associated with specific force deficit. Excess superoxide generation from the mitochondrial complexes causes a deficiency of succinate dehydrogenase and reduced complex-II-mediated respiration and adenosine triphosphate generation rates leading to severe exercise intolerance (~10 min vs. ~2 h in wild type, P < 0.05). Increased skeletal muscle mtROS is sufficient to elicit NMJ disruption and contractile abnormalities, but not muscle atrophy, suggesting new roles for mitochondrial oxidative stress in maintenance of muscle mass through increased fiber branching. <small>© 2019 The Authors. Journal of Cachexia, Sarcopenia and Muscle published by John Wiley & Sons Ltd on behalf of the Society on Sarcopenia, Cachexia and Wasting Disorders.</small>  

Age-related muscle atrophy and weakness, or sarcopenia, are significant contributors to compromised health and quality of life in the elderly. While the mechanisms driving this pathology are not fully defined, reactive oxygen species, neuromuscular junction (NMJ) disruption, and loss of innervation are important risk factors. The goal of this study is to determine the impact of mitochondrial hydrogen peroxide on neurogenic atrophy and contractile dysfunction. Mice with muscle-specific overexpression of the mitochondrial H₂O₂ scavenger peroxiredoxin3 (mPRDX3) were crossed to Sod1KO mice, an established mouse model of sarcopenia, to determine whether reduced mitochondrial H₂O₂ can prevent or delay the redox-dependent sarcopenia. Basal rates of H₂O₂ generation were elevated in isolated muscle mitochondria from Sod1KO, but normalized by mPRDX3 overexpression. The mPRDX3 overexpression prevented the declines in maximum mitochondrial oxygen consumption rate and calcium retention capacity in Sod1KO. Muscle atrophy in Sod1KO was mitigated by ~20% by mPRDX3 overexpression, which was associated with an increase in myofiber cross-sectional area. With direct muscle stimulation, maximum isometric specific force was reduced by ~20% in Sod1KO mice, and mPRDX3 overexpression preserved specific force at wild-type levels. The force deficit with nerve stimulation was exacerbated in Sod1KO compared to direct muscle stimulation, suggesting NMJ disruption in Sod1KO. Notably, this defect was not resolved by overexpression of mPRDX3. Our findings demonstrate that muscle-specific PRDX3 overexpression reduces mitochondrial H₂O₂ generation, improves mitochondrial function, and mitigates loss of muscle quantity and quality, despite persisting NMJ impairment in a murine model of redox-dependent sarcopenia.  +

The Tim23 protein is the key component of the mitochondrial import machinery. It locates to the inner mitochondrial membrane and its own import is dependent on the DDP1/TIM13 complex. Mutations in human DDP1 cause the Mohr-Tranebjaerg syndrome (MTS/DFN-1; OMIM #304700), which is one of the two known human diseases of the mitochondrial protein import machinery. We created a ''Tim23'' knockout mouse from a gene trap embryonic stem cell clone. Homozygous Tim23 mice were not viable. Heterozygous F1 mutants showed a 50% reduction of Tim23 protein in Western blot, a ''neurological phenotype'' and a markedly reduced life span. Haploinsufficiency of the ''Tim23'' mutation underlines the critical role of the mitochondrial import machinery for maintaining mitochondrial function.  +

[[Image:MITOEAGLE-logo.jpg|left|100px|link=http://www.mitoglobal.org/index.php/MITOEAGLE|COST Action MitoEAGLE]] Mutations in Wfs1 gene, which are responsible for synthesis of transmembrane endoplasmatic reticulum (ER) protein wolframin, cause a multi-targeting disease Wolfram syndrome (WS). The first symptom of the WS is diabetes mellitus, followed in most cases by optic atrophy, diabetes insipidus and deafness. Also, link between Wfs1 deficiency and mitochondrial dysfunction have shown, causing neurological degeneration, ataxia and alteration in heart and skeletal muscle performance [1]. WS is accompanied with progressive loss of pancreatic β-cells cell caused by alterations in cellular Ca²⁺ signaling related to ER stress and unfolded protein responses [2]. The precise role of wolframin and pathophysiology at organism level is still poorly understood. We used Wfs1KO mice characterized with impaired glucose tolerance and an activated pathway characteristic for metabolic diseases [3]. Aim of the study is to follow alterations in OXPHOS capacity and phosphotransfer networks caused by Wfs1 deficiency in different muscle types: oxidative heart and soleus muscle and glycolytic ''m. rectus femoris'' and ''m. gastrocnemius'' white. Our results showed that all the studied muscles Wfs1KO mouse has a maximal of ADP-dependent respiration rate with glutamate and malate lower than that of wild-type (WT) animals. However, when pyruvate and malate is used as substrate, no significant difference was detected. At the same time the leak state without adenylates is higher in Wfs1KO in most muscles with both complex I substrate combinations used. At the same time respiration rates with succinate were unaffected by Wfs1 deficiency. It indicates to metabolic alterations in supporting of OXPHOS at the level of complex I. Facilitated energy transfer by creatine kinase (CK), adenylate kinase (AK) and other energy transport pathways is governed by the metabolic status of the cell [4]. In Wfs1KO mice heart muscle AK pathway was more active than WT, while the creatine activated respiration is lower than WT. On the contrary, in the glycolytic m. rectus femoris the activity of AK pathway shows a slight decrease in comparison to the control. Results in energy transfer pathways in the heart and skeletal muscles of Wfs1KO mice indicate shift a in the energy pathway preferences. In addition, Wfs1KO mice showed changes in the coupling between OXPHOS and glycolysis in oxidative cardiac and in glycolytic gastrocnemius white muscle. These changes indicate to compensatory mechanism in response to metabolic alterations.  

Metabolic dysfunction and mitochondrial involvement are recognised as part of the pathology in Huntington's Disease (HD). Post-mortem examinations of the striatum from end-stage HD patients have shown a decrease in the ''in vitro'' activity of Complexes II, III and IV of the electron transfer-pathway (ET-pathway). In different models of HD, evidence of enzyme defects have been reported in Complex II and Complex IV using enzyme assays. However, such assays are highly variable and results have been inconsistent. We investigated the integrated ET-pathway function ex vivo using a sensitive high-resolution respirometric (HRR) method. The O2 flux in a whole-cell sample combined with the addition of mitochondrial substrates, uncouplers and inhibitors enabled us to accurately quantitate the function of individual mitochondrial complexes in intact mitochondria, while retaining mitochondrial regulation and compensatory mechanisms. We used HRR to examine the mitochondrial function in striata from 12-week old R6/2 mice expressing exon 1 of human HTT with 130 CAG repeats. A significant reduction in Complex II and Complex IV flux control ratios was found in the R6/2 mouse striatum at 12 weeks of age compared to controls, confirming previous findings obtained with spectrophotometric enzyme assays.  +

Der menschliche Körper besteht aus 10 bis 100 Billionen Zellen - und jede ist ein Wunderwerk für sich. Zellen können sich teilen, bilden Proteine, nehmen Sauerstoff auf und geben Botenstoffe, aber auch Giftstoffe ab, sie enthalten Erbgut und im Zellkern ist außerdem gespeichert, welche Aufgabe die zelle zu erfüllen hat. Im menschlichen Körper gibt es rund 100 verschieden spezialisierte Zellen: etwa rote Blutzellen die für den Suaerstofftransport zuständig sind oder Nervenzellen, die Informationen transportieren. ...  +

Karyomegalic interstitial nephritis (KIN) is a genetic adult-onset chronic kidney disease (CKD) characterized by genomic instability and mitotic abnormalities in the tubular epithelial cells. KIN is caused by recessive mutations in the FAN1 DNA repair enzyme. However, the endogenous source of DNA damage in FAN1/KIN kidneys has not been identified. Here we show, using FAN1-deficient human renal tubular epithelial cells (hRTECs) and FAN1-null mice as a model of KIN, that FAN1 kidney pathophysiology is triggered by hypersensitivity to endogenous reactive oxygen species (ROS), which cause chronic oxidative and double-strand DNA damage in the kidney tubular epithelial cells, accompanied by an intrinsic failure to repair DNA damage. Furthermore, persistent oxidative stress in FAN1-deficient RTECs and FAN1 kidneys caused mitochondrial deficiencies in oxidative phosphorylation and fatty acid oxidation. The administration of subclinical, low-dose cisplatin increased oxidative stress and aggravated mitochondrial dysfunction in FAN1-deficient kidneys, thereby exacerbating KIN pathophysiology. In contrast, treatment of FAN1 mice with a mitochondria-targeted ROS scavenger, JP4-039, attenuated oxidative stress and accumulation of DNA damage, mitigated tubular injury, and preserved kidney function in cisplatin-treated FAN1-null mice, demonstrating that endogenous oxygen stress is an important source of DNA damage in FAN1-deficient kidneys and a driver of KIN pathogenesis. Our findings indicate that therapeutic modulation of kidney oxidative stress may be a promising avenue to mitigate FAN1/KIN kidney pathophysiology and disease progression in patients.  +

One of the basic aspects of the cancer problem, the energy metabolism of neoplastic tissue, is presented in this monograph which covers the anaerobic and aerobic glycolysis of normal and tumor tissue, the oxidative metabolism of the tumors, and the regulatory mechanism in respiration and glycolysis. Almost 40 years after Warburg's fundamental studies, the present state of our knowledge of metabolism and biochemistry of tumors has found a competent and critical evaluation in this book  +

Apart from its adverse effects on the respiratory system, cigarette smoking also induces skeletal muscle atrophy and dysfunction. Whether short-term smoking cessation can restore muscle mass and function is unknown. We therefore studied the impact of 1- and 2-weeks smoking cessation on skeletal muscles in a mouse model. Male mice were divided into 4 groups: Air-exposed (14 weeks); cigarette smoke (CS)-exposed (14 weeks); CS-exposed (13 weeks) followed by 1-week cessation; CS-exposed (12 weeks) followed by 2 weeks cessation to examine exercise capacity, physical activity levels, body composition, muscle function, capillarization, mitochondrial function and protein expression in the soleus, plantaris and diaphragm muscles. CS-induced loss of body and muscle mass was significantly improved within 1 week of cessation due to increased lean and fat mass. Mitochondrial respiration and protein levels of the respiratory complexes in the soleus were lower in CS-exposed mice, but similar to control values after 2 weeks of cessation. Exposing isolated soleus muscles to CS extracts reduced mitochondrial respiration that was reversed after removing the extract. While physical activity was reduced in all groups, exercise capacity, limb muscle force, fatigue resistance, fiber size and capillarization and diaphragm cytoplasmic HIF-1α were unaltered by CS-exposure. However, CS-induced diaphragm atrophy and increased capillary density was not seen after 2 weeks of smoking cessation. In male mice, two weeks smoking cessation reversed smoking-induced mitochondrial dysfunction, limb muscle mass loss and diaphragm muscle atrophy, highlighting immediate benefits of cessation on skeletal muscles. <small>© The Author(s) 2020. Published by Oxford University Press on behalf of the Society for Research on Nicotine and Tobacco. All rights reserved. For permissions, please e-mail: [email protected].</small>  +

O-GlcNAcylation is a prevalent form of glycosylation that regulates proteins within the cytosol, nucleus, and mitochondria. The O-GlcNAc modification can affect protein cellular localization, function, and signaling interactions. The specific impact of O-GlcNAcylation on mitochondrial morphology and function has been elusive. In this manuscript, the role of O-GlcNAcylation on mitochondrial fission, oxidative phosphorylation (Oxphos), and the activity of electron transport chain (ETC) complexes were evaluated. In a cellular environment with hyper O-GlcNAcylation due to the deletion of O-GlcNAcase (OGA), mitochondria showed a dramatic reduction in size and a corresponding increase in number and total mitochondrial mass. Because of the increased mitochondrial content, OGA knockout cells exhibited comparable coupled mitochondrial Oxphos and ATP levels when compared to WT cells. However, we observed reduced protein levels for complex I and II when comparing normalized mitochondrial content and reduced linked activity for complexes I and III when examining individual ETC complex activities. In assessing mitochondrial fission, we observed increased amounts of O-GlcNAcylated dynamin-related protein 1 (Drp1) in cells genetically null for OGA and in glioblastoma cells. Individual regions of Drp1 were evaluated for O-GlcNAc modifications, and we found that this post-translational modification (PTM) was not limited to the previously characterized residues in the variable domain (VD). Additional modification sites are predicted in the GTPase domain, which may influence enzyme activity. Collectively, these results highlight the impact of O-GlcNAcylation on mitochondrial dynamics and ETC function and mimic the changes that may occur during glucose toxicity from hyperglycemia.  +

'''OBJECTIVE:''' Impairments in mitochondrial function have been proposed to play a role in the etiology of diabetic sensory neuropathy. We tested the hypothesis that mitochondrial dysfunction in axons of sensory neurons in type 1 diabetes is due to abnormal activity of the respiratory chain and an altered mitochondrial proteome. '''RESEARCH DESIGN AND METHODS:''' Proteomic analysis using stable isotope labeling with amino acids in cell culture (SILAC) determined expression of proteins in mitochondria from dorsal root ganglia (DRG) of control, 22-week-old streptozotocin (STZ)-diabetic rats, and diabetic rats treated with insulin. Rates of oxygen consumption and complex activities in mitochondria from DRG were measured. Fluorescence imaging of axons of cultured sensory neurons determined the effect of diabetes on mitochondrial polarization status, oxidative stress, and mitochondrial matrix-specific reactive oxygen species (ROS). '''RESULTS:''' Proteins associated with mitochondrial dysfunction, oxidative phosphorylation, ubiquinone biosynthesis, and the citric acid cycle were downregulated in diabetic samples. For example, cytochrome c oxidase subunit IV (COX IV; a Complex IV protein) and NADH dehydrogenase Fe-S protein 3 (NDUFS3; a Complex I protein) were reduced by 29 and 36% (''P'' < 0.05), respectively, in diabetes and confirmed previous Western blot studies. Respiration and mitochondrial complex activity was significantly decreased by 15 to 32% compared with control. The axons of diabetic neurons exhibited oxidative stress and depolarized mitochondria, an aberrant adaption to oligomycin-induced mitochondrial membrane hyperpolarization, but reduced levels of intramitochondrial superoxide compared with control. '''CONCLUSIONS:''' Abnormal mitochondrial function correlated with a downregulation of mitochondrial proteins, with components of the respiratory chain targeted in lumbar DRG in diabetes. The reduced activity of the [[respiratory chain]] was associated with diminished superoxide generation within the mitochondrial matrix and did not contribute to oxidative stress in axons of diabetic neurons. Alternative pathways involving polyol pathway activity appear to contribute to raised ROS in axons of diabetic neurons under high glucose concentration.  

Mammalian cell culture is foundational to biomedical research, and the reproducibility of research findings across the sciences is drawing increasing attention. While many components contribute to reproducibility, the reporting of factors that impact oxygen delivery in the general biomedical literature has the potential for both significant impact, and immediate improvement. The relationship between the oxygen consumption rate of cells and the diffusive delivery of oxygen through the overlying medium layer means parameters such as medium depth and cell type can cause significant differences in oxygenation for cultures nominally maintained under the same conditions. While oxygenation levels are widely understood to significantly impact the phenotype of cultured cells in the abstract, in practise the importance of the above parameters does not appear to be well recognized in the non-specialist research community. On analyzing two hundred articles from high-impact journals we find a large majority missing at least one key piece of information necessary to ensure consistency in replication. We propose that explicitly reporting these values should be a requirement for publication.  +

Rheumatoid arthritis (RA) is the major autoimmune destructive disease of joints with a complicated pathogenesis. The contribution of tumor necrosis factor-like ligand 1A (TL1A) in RA pathogenesis, especially on fibroblast-like synoviocytes (FLS), has been suggested clinically. The present study investigated the role of TL1A in mitochondrial dysfunction, induced oxidative stress in mitochondria, apoptosis resistance and the inflammatory response in FLS obtained from RA patients (RA-FLS). RA-FLS were incubated with TL1A and tumor necrosis factor receptor 2 (TNFR2) antagonist. Respiratory function, mitochondrial membrane potential and respiration associated genes of mitochondria were measured in both TL1A stimulated and non-stimulated RA-FLS. Additionally, the effects of TL1A on reactive oxygen species (ROS) production in mitochondria, apoptosis and the inflammatory response in RA-FLS were also assessed. The role of TL1A in association between ROS generation, especially mitochondrial type and the inflammatory response, was evaluated by measuring inflammation-related cytokines and signaling pathways using ROS inhibitors, diphenyleneiodonium chloride and Mito-TEMPO (Sigma-Aldrich, Miamisburg, OH, USA). We found that TL1A induced mitochondrial dysfunction by weakening mitochondrial respiration and membrane potential, which was blocked by a TNFR2 antagonist. Increased ROS synthesis in impaired mitochondria was observed with MitoSOX (Invitrogen, CA, USA) immunofluorescence staining in TL1A-stimulated RA-FLS but inhibited by a TNFR2 antagonist. TL1A influenced apoptosis resistance and inflammatory mediators via TNFR2. Inhibition of mitochondria-derived ROS compromised the production of inflammatory factors in TL1A-stimulated RA-FLS, suggesting that mitochondrial dysfunction mediated by the TL1A/TNFR2 axis might amplify the inflammatory response via regulation of mitochondria-derived ROS generation. Collectively, our results reveal that TL1A might be involved in making FLS more aggressive in RA pathogenesis via cell respiration interruption. <small>© 2020 Federation of European Biochemical Societies.</small>  

The reference organ-level body composition measurement method is MRI. Practical estimations of total adipose tissue mass (TATM), total adipose tissue fat mass (TATFM) and total body fat are valuable for epidemiology, but validated prediction equations based on MRI are not currently available. We aimed to derive and validate new anthropometric equations to estimate MRI-measured TATM/TATFM/total body fat and compare them with existing prediction equations using older methods. The derivation sample included 416 participants (222 women), aged between 18 and 88 years with BMI between 15·9 and 40·8 (kg/m2). The validation sample included 204 participants (110 women), aged between 18 and 86 years with BMI between 15·7 and 36·4 (kg/m2). Both samples included mixed ethnic/racial groups. All the participants underwent whole-body MRI to quantify TATM (dependent variable) and anthropometry (independent variables). Prediction equations developed using stepwise multiple regression were further investigated for agreement and bias before validation in separate data sets. Simplest equations with optimal R (2) and Bland-Altman plots demonstrated good agreement without bias in the validation analyses: men: TATM (kg)=0·198 weight (kg)+0·478 waist (cm)-0·147 height (cm)-12·8 (validation: R 2 0·79, CV=20 %, standard error of the estimate (SEE)=3·8 kg) and women: TATM (kg)=0·789 weight (kg)+0·0786 age (years)-0·342 height (cm)+24·5 (validation: R (2) 0·84, CV=13 %, SEE=3·0 kg). Published anthropometric prediction equations, based on MRI and computed tomographic scans, correlated strongly with MRI-measured TATM: (R (2) 0·70-0·82). Estimated TATFM correlated well with published prediction equations for total body fat based on underwater weighing (R (2) 0·70-0·80), with mean bias of 2·5-4·9 kg, correctable with log-transformation in most equations. In conclusion, new equations, using simple anthropometric measurements, estimated MRI-measured TATM with correlations and agreements suitable for use in groups and populations across a wide range of fatness.  

Porcine model of peritonitis-induced sepsis is a well-established clinically relevant model of human disease. Interindividual variability of the response often complicates the interpretation of findings. To better understand the biological basis of the disease variability, the progression of the disease was compared between animals with sepsis and septic shock. Peritonitis was induced by inoculation of autologous feces in fifteen anesthetized, mechanically ventilated and surgically instrumented pigs and continued for 24 h. Cardiovascular and biochemical parameters were collected at baseline (just before peritonitis induction), 12 h, 18 h and 24 h (end of the experiment) after induction of peritonitis. Analysis of multiple parameters revealed the earliest significant differences between sepsis and septic shock groups in the sequential organ failure assessment (SOFA) score, systemic vascular resistance, partial pressure of oxygen in mixed venous blood and body temperature. Other significant functional differences developed later in the course of the disease. The data indicate that SOFA score, hemodynamical parameters and body temperature discriminate early between sepsis and septic shock in a clinically relevant porcine model. Early pronounced alterations of these parameters may herald a progression of the disease toward irreversible septic shock.  +

Previously, we showed that fluvastatin treatment induces myofibrillar damage and mitochondrial phenotypes in the skeletal muscles of ''Drosophila''. However, the sequential occurrence of mitochondrial phenotypes and myofibril damage remains elusive. To address this, we treated flies with fluvastatin for two and five days and examined their thorax flight muscles using confocal microscopy. In the two-day fluvastatin group, compared to the control, thorax flight muscles exhibited mitochondrial morphological changes, including fragmentation, rounding up and reduced content, while myofibrils remained organized in parallel. In the five-day fluvastatin treatment, not only did mitochondrial morphological changes become more pronounced, but myofibrils became severely disorganized with significantly increased thickness and spacing, along with myofilament abnormalities, suggesting myofibril damage. These findings suggest that fluvastatin-induced mitochondrial changes precede myofibril damage. Moreover, in the five-day fluvastatin group, the mitochondria demonstrated elevated H₂O₂ and impaired fatty acid oxidation compared to the control group, indicating potential mitochondrial dysfunction. Surprisingly, knocking down Hmgcr (''Drosophila'' homolog of HMGCR) showed normal mitochondrial respiration in all parameters compared to controls or five-day fluvastatin treatment, which suggests that fluvastatin-induced mitochondrial dysfunction might be independent of Hmgcr inhibition. These results provide insights into the sequential occurrence of mitochondria and myofibril damage in statin-induced myopathy for future studies.  +

Leigh syndrome is a progressive neurodegenerative disorder, most commonly observed in paediatric mitochondrial disease, and is often associated with pathogenic variants in complex I structural subunits or assembly factors resulting in isolated respiratory chain complex I deficiency. Clinical heterogeneity has been reported, but key diagnostic findings are developmental regression, elevated lactate and characteristic neuroimaging abnormalities. Here, we describe three affected children from two unrelated families who presented with Leigh syndrome due to homozygous variants (c.346_*7del and c.173A>T p.His58Leu) in NDUFC2, encoding a complex I subunit. Biochemical and functional investigation of subjects' fibroblasts confirmed a severe defect in complex I activity, subunit expression and assembly. Lentiviral transduction of subjects' fibroblasts with wild-type NDUFC2 cDNA increased complex I assembly supporting the association of the identified NDUFC2 variants with mitochondrial pathology. Complexome profiling confirmed a loss of NDUFC2 and defective complex I assembly, revealing aberrant assembly intermediates suggestive of stalled biogenesis of the complex I holoenzyme and indicating a crucial role for NDUFC2 in the assembly of the membrane arm of complex I, particularly the ND2 module.  +

[[Image:MITOEAGLE-logo.jpg|left|100px|link=http://www.mitoglobal.org/index.php/MITOEAGLE|COST Action MITOEAGLE]] Mitochondrial F₁F_O ATP synthase is the key enzyme of the oxidative phosphorylation apparatus, responsible for the production of up to 90% of the cellular ATP. The mammalian enzyme is composed of 17 structural subunits – two of the recently characterized ones (MLQ and DAPIT) are specific for higher eukaryotes. MLQ, also termed 6.8 kDa proteolipid (MP68), is nuclearly encoded protein with 58 amino acids, containing one putative membrane domain. The complete structure of MLQ, its stoichiometry within the enzyme, or its exact localization in the F_O domain is as of yet unknown. To clarify the biological role of MLQ, we created a MLQ knock-out model in the HEK293 cells by the CRISPR/Cas9 technology. We demonstrate defective biogenesis of the fully assembled ATP synthase in the absence of MLQ. While mitochondrially encoded subunits F_O-a and A6L are synthesized and assembled into the complex, MLQ is required for their stabilization in the holoenzyme. In its absence, F_O-a and A6L dissociate and are degraded as confirmed by pulse chase experiments. As a result, at the steady state, incomplete enzyme lacking the proton channel formed by subunit F_O-a is present in MLQ -/- mitochondria. At the functional level, we observed significantly reduced rates of ADP stimulated respiration in MLQ -/- cells, while the hydrolytic activity of the ATP synthase was preserved. Secondary to the ATP synthase deficiency we observed decreased mRNA and protein levels of the mitochondrially encoded subunits of cytochrome ''c'' oxidase (CIV). This led to the reduced levels of COX holoenzyme and decrease in ATP synthase independent state 3 (FCCP) respiration. We will discuss the molecular role of MLQ in F₁F_O ATP synthase assembly as well as the functional impact of MLQ KO on the cellular energetics. Moreover, we will report on progress of F_O-a and A6L subunits degradation mechanism in MLQ KO cells.  

'''Authors:''' [[Alan Lukas]], [[Calvo E]], [[Enriquez Jose A]], [[Soriano ME]], [[Bean C]], [[Mracek Tomas]] and [[Scorrano Luca]]<br><br> '''Introduction:''' Obesity is turning into a worldwide pandemic, with most patients also affected by other comorbidities such as type 2 diabetes, hypertension, or cardiovascular disease. With mitochondria being a major site for fatty acid oxidation, they represent an important target for obesity treatment. Mitochondria are dynamic organelles, and their morphology influences both the organization of membrane protein complexes as well as mitochondrial substrate preference1. <br> '''Methods:''' By combining 2-dimension blue native gel electrophoresis with proteomics and bioinformatics in heart mitochondria undergoing membrane remodelling we identified a strong correlation between the key cristae biogenesis protein Opa1 and Vwa8, a putative AAA+ ATPase with a dynein conformation. In order to study the role of Vwa8 protein in mitochondrial physiology, we developed the HEK293 Vwa8 knock-out cell line and Vwa8 KO mice.<br> '''Results and discussion:''' Vwa8 protein localized to the mitochondrial intermembrane space where it formed discrete spots. Deletion of Vwa8 led to an increase in mitochondrial respiration on fatty acids but not on glucose or glutamine. The Vwa8 KO mice showed decreased resting energy requirements as well as higher heat production, indicating a stronger preference for lipid oxidation. Moreover, the subcutaneous adipose tissue of Vwa8 KO mice showed increased markers of browning such as an increase in mitochondria content and lipid droplet multilocularity. The Vwa8 KO mice remained more insulin sensitive and with higher lean mass proportion upon a high-fat diet. In conclusion, Vwa8 affects mitochondrial substrate preference, induces browning of subcutaneous adipose tissue and represents a new target for obesity treatment.<br> <small> # Alan L, Scorrano L. (2022) Shaping fuel utilization by mitochondria. Curr Biol. 2022 Jun 20;32(12):R618-R623. doi: 10.1016/j.cub.2022.05.006. </small>  

Infection with the challenge virus standard-11 (CVS) strain of fixed rabies virus induces neuronal process degeneration in adult mice after hindlimb footpad inoculation. CVS-induced axonal swellings of primary rodent dorsal root ganglion neurons are associated with 4-hydroxy-2-nonenal protein adduct staining, indicating a critical role of oxidative stress. Mitochondrial dysfunction is the major cause of oxidative stress. We hypothesized that CVS infection induces mitochondrial dysfunction leading to oxidative stress. We investigated the effects of CVS infection on several mitochondrial parameters in different cell types. CVS infection significantly increased maximal uncoupled respiration and complex IV respiration and complex I and complex IV activities, but did not affect complex II-III or citrate synthase activities. Increases in complex I activity, but not complex IV activity, correlated with susceptibility of the cells to CVS infection. CVS infection maintained coupled respiration and rate of proton leak, indicating a tight mitochondrial coupling. Possibly as a result of enhanced complex activity and efficient coupling, a high mitochondrial membrane potential was generated. CVS infection reduced the intracellular ATP level and altered the cellular redox state as indicated by a high NADH/NAD+ ratio. The basal production of reactive oxygen species (ROS) was not affected in CVS-infected neurons. However, a higher rate of ROS generation occurred in CVS-infected neurons in the presence of mitochondrial substrates and inhibitors. We conclude that CVS infection induces mitochondrial dysfunction leading to ROS overgeneration and oxidative stress.  +

When long-chain fatty acids enter the cells, long-chain acyl-CoA synthases (ACSLs) convert them to acyl-CoAs in an ATP-dependent reaction. The resulting acyl-CoAs have numerous metabolic routes within cells, including incorporation into triacylglycerol (TAG) and membrane phospholipids. Acyl-CoAs are used as substrates for beta-oxidation and protein acylation and function as ligands for transcription factors. However, the function of ACSL6 in skeletal muscle cells has not been described. The aim of this study was to investigate the effects of ACSL6 knockdown on mitochondrial metabolism in skeletal muscle cells. Isolation of primary rat skeletal muscle cells from the lower limb was performed by collagenase II digestion [1]. Knockdown of ACSL6 was made by siRNA specific transfection. After the knockdown, the cells were collected for the following experiments: mRNA expression (RT-PCR), MS-MS lipid analyzes, cell viability (flow cytometry), oxygen consumption (Oroboros Oxygraph-2k) [2] and reactive oxygen species (ROS) production (Amplex UltraRed). ACSL6 siRNA transfection (20 nM) reduced the expression of ACSL6 mRNA by 70±8%. ACSL6 knockdown increased the free fatty acids C16:0 and C18:0 by 32±3% and 35±3%, respectively. siRNA transfection did not affect cell viability measured by propide iodate. ACSL6 genic silencing increased mitochondrial respiration in all states [pmol O2∙s⁻¹∙10⁻⁶ cells]: ROUTINE respiration (297±30 vs 368±28), LEAK with oligomycin (91±5 vs 96±4) and noncoupled ET-pathway (610±45 vs 703±41), and decreased ROS production (''P''<0.05). ACSL6 genic silencing increased mRNA expression of oxidative genes PGC1 (~50%), UCP2 (~3 fold) and UCP3 (~5 fold), decreased mRNA expression of ACSL3 and had no effect on ACSL1 and β-hydroxyacyl-CoA dehydrogenase (β-HAD). ACSL6 knockdown increased the availability of free fatty acids, which are major regulators of UCP’s. This may reflect the action of signaling pathways which remodel the oxidative program of skeletal muscle cells, increasing mitochondrial respiration. These mechanisms may contribute to control metabolic diseases, such as insulin resistance and obesity.  

[[File:Eva albertini.jpg|right|150px|Eva Albertini]] Availability of methionine is known to modulate the rate of aging in model organisms, best illustrated by the observation that dietary methionine restriction extends the lifespan of rodents. However, the underlying mechanisms are incompletely understood. In eukaryotic cells, methionine can be converted to cysteine through the reverse transsulfuration pathway thereby modulating intracellular methionine availability. Whereas previous results obtained in yeast and fruit flies suggest that alterations in the reverse transsulfuration pathway modulate the rate of aging, it is not known whether this function is conserved in evolution. Here we show that depletion of cystathionine beta synthase (CBS), a rate limiting enzyme in the reverse transsulfuration pathway, induces premature senescence in human endothelial cells. We found that CBS depletion induces mild mitochondrial dysfunction and increases the sensitivity of endothelial cells to homocysteine, a known inducer of endothelial cell senescence and an established risk factor for vascular disease. Our finding that CBS deficiency induces endothelial cell senescence in vitro, involving both mitochondrial dysfunction and increased susceptibility of the cells to homocysteine, suggests a new mechanism linking CBS deficiency to vascular aging and disease. # [[Albertini 2012 Aging (Albany NY)|Albertini E, Kozieł R, Duerr A, Neuhaus M, Jansen-Duerr P (2012) Cystathionine beta synthase modulates senescence of human endothelial cells. Aging (Albany NY) 4:664-73.]]  +

Availability of methionine is known to modulate the rate of aging in model organisms, best illustrated by the observation that dietary methionine restriction extends the lifespan of rodents. However, the underlying mechanisms are incompletely understood. In eukaryotic cells, methionine can be converted to cysteine through the reverse transsulfuration pathway thereby modulating intracellular methionine availability. Whereas previous results obtained in yeast and fruit flies suggest that alterations in the reverse transsulfuration pathway modulate the rate of aging, it is not known whether this function is conserved in evolution. Here we show that depletion of cystathionine beta synthase (CBS), a rate limiting enzyme in the reverse transsulfuration pathway, induces premature senescence in human endothelial cells. We found that CBS depletion induces mild mitochondrial dysfunction and increases the sensitivity of endothelial cells to homocysteine, a known inducer of endothelial cell senescence and an established risk factor for vascular disease. Our finding that CBS deficiency induces endothelial cell senescence ''in vitro'', involving both mitochondrial dysfunction and increased susceptibility of the cells to homocysteine, suggests a new mechanism linking CBS deficiency to vascular aging and disease.  +

This SI version of the fifth edition has bee prepared for those who want to use the joule in thermodynamic calculations and SI units more completely in other sections. The calorie has been replaced by the joule (1 cal = 4.184 J), the torr has been replaced by the pascal (1 torr = 133.322 Pa), and the gauss has been replaced by the tesla (1 G = 10^-4 T). In calculations using other quantities in SI units, pressures are expressed in pascals. This has real advantages in calculations because the SI system is coherent; that is, no additional numerical factors appear in equations relating different physical quantities. Thermodynamics deals with relationships between properties of systems at equilibrium and with differences in properties between various equilibrium states. It has nothing to do with time. Even so, it is one of the most powerful tools of physical chemistry.  +

In addition to the conventional cytochrome c oxidase, mitochondria of all plants studied to date contain a second cyanide-resistant terminal oxidase or alternative oxidase (AOX). The AOX is located in the inner mitochondrial membrane and branches from the cytochrome pathway at the level of the quinone pool. It is non-protonmotive and couples the oxidation of ubiquinone to the reduction of oxygen to water. For many years, the AOX was considered to be confined to plants, fungi and a small number of protists. Recently, it has become apparent that the AOX occurs in wide range of organisms including prokaryotes and a moderate number of animal species. In this paper, we provide an overview of general features and current knowledge available about the AOX with emphasis on structure, the active site and quinone-binding site. Characterisation of the AOX has advanced considerably over recent years with information emerging about the role of the protein, regulatory regions and functional sites. The large number of sequences available is now enabling us to obtain a clearer picture of evolutionary origins and diversity.  +

Impaired AMPK is associated with a wide spectrum of clinical and pathological conditions, ranging from obesity, altered responses to exercise or metabolic syndrome, to inflammation, disturbed mitochondrial biogenesis and defective response to energy stress. Fibromyalgia (FM) is a world-wide diffused musculoskeletal chronic pain condition that affects up to 5% of the general population and comprises all the above mentioned pathophysiological states. Here, we tested the involvement of AMPK activation in fibroblasts derived from FM patients. AMPK was not phosphorylated in fibroblasts from FM patients and was associated with decreased mitochondrial biogenesis, reduced oxygen consumption, decreased antioxidant enzymes expression levels and mitochondrial dysfunction. However, mtDNA sequencing analysis did not show any important alterations which could justify the mitochondrial defects. AMPK activation in FM fibroblast was impaired in response to moderate oxidative stress. In contrast, AMPK activation by metformin or incubation with serum from caloric restricted mice improved the response to moderate oxidative stress and mitochondrial metabolism in FM fibroblasts. These results suggest that AMPK plays an essential role in FM pathophysiology and could represent the basis for a valuable new therapeutic target/strategy. Furthermore, both metformin and caloric restriction could be an interesting therapeutic approach in FM. Copyright © 2015 Elsevier B.V. All rights reserved.  +

Coenzyme Q (CoQ) is a unique electron carrier in the mitochondrial respiratory chain, which is synthesized on-site by a nuclear encoded multiprotein complex. CoQ receives electrons from different redox pathways, mainly NADH and FADH2 from tricarboxylic acid pathway, dihydroorotate dehydrogenase, electron transfer flavoprotein dehydrogenase and glycerol-3-phosphate dehydrogenase that support key aspects of the metabolism. Here we explore some lines of evidence supporting the idea of the interaction of CoQ with the respiratory chain complexes, contributing to their superassembly, including respirasome, and its role in reactive oxygen species production in the mitochondrial inner membrane. We also review the current knowledge about the involvement of mitochondrial genome defects and electron transfer flavoprotein dehydrogenase mutations in the induction of secondary CoQ deficiency. This mechanism would imply specific interactions coupling CoQ itself or the CoQ-biosynthetic apparatus with the respiratory chain components. These interactions would regulate mitochondrial CoQ steady-state levels and function. This article is part of a Special Issue entitled 'EBEC 2016: 19th European Bioenergetics Conference, Riva del Garda, Italy, July 2-6, 2016', edited by Prof. Paolo Bernardi.  +

We show that the cyclin-dependent kinase inhibitor 1B (CDKN1B)/p27, previously known as a cell cycle inhibitor, is also localized within mitochondria. The migratory capacity of endothelial cells, which need intact mitochondria, is completely dependent on mitochondrial p27. Mitochondrial p27 improves mitochondrial membrane potential, increases adenosine triphosphate (ATP) content, and is required for the promigratory effect of caffeine. Domain mapping of p27 revealed that the N-terminus and C-terminus are required for those improvements. Further analysis of those regions revealed that the translocation of p27 into the mitochondria and its promigratory activity depend on serine 10 and threonine 187. In addition, mitochondrial p27 protects cardiomyocytes against apoptosis. Moreover, mitochondrial p27 is necessary and sufficient for cardiac myofibroblast differentiation. In addition, p27 deficiency and aging decrease respiration in heart mitochondria. Caffeine does not increase respiration in p27-deficient animals, whereas aged mice display improvement after 10 days of caffeine in drinking water. Moreover, caffeine induces transcriptome changes in a p27-dependent manner, affecting mostly genes relevant for mitochondrial processes. Caffeine also reduces infarct size after myocardial infarction in prediabetic mice and increases mitochondrial p27. Our data characterize mitochondrial p27 as a common denominator that improves mitochondria-dependent processes and define an increase in mitochondrial p27 as a new mode of action of caffeine.  +

Literature Watch 969 BY MARIA-LUISA ALEGRE, MD, PHD Regulatory T cells that express the transcription factor FoxP3 (Tregs) are essential for the maintenance of immune homeostasis. A lack of Tregs at birth, Treg deletion in adulthood or the selective ablation of the T cell receptor (TCR) in Tregs or of key membrane-associated or signaling molecules, such as CTLA-4, CD28 or PTEN, have been shown in mice to lead to dramatic lymphoproliferative disease, tissue infiltration by activated conventional T cells (Tconvs) and, in many cases, animal death. This underscores the importance of continuous and proper activation of Tregs throughout life. Tregs have a unique metabolic profile, including greater mitochondrial metabolism than Tconvs. Weinberg and colleagues investigate whether mitochondrial respiration (Figure 1) is necessary for the ability of Tregs to maintain homeostasis, and find that tampering with Treg–mitochondrial complex III triggers fatal autoimmunity.  +

[[File:BEC.png|25px|link=https://doi.org/10.26124/bec:2022-0017]] https://doi.org/10.26124/bec:2022-0017<br> The parasite ''Trypanosoma brucei'' is the causative agent of sleeping sickness and involves an insect vector and a mammalian host through its complex life cycle. T. brucei mammalian bloodstream forms (BSF) exhibits unique metabolic features including: (''1'') reduced expression and activity of mitochondrial enzymes; (''2'') respiration mediated by the glycerol phosphate shuttle (GPSh) and the Trypanosome alternative oxidase (TAO) that is intrinsically uncoupled from generation of mitochondrial protonmotive force; (''3'') maintenance of mitochondrial membrane potential by ATP hydrolysis through the reversal of F1FO-ATP synthase activity; (''4'') strong reliance on glycolysis to meet their energy demands; (''5'') high susceptibility to oxidants. Here, we critically review the main metabolic features of BSF and provide a hypothesis to explain the unusual metabolic network and its biological significance for this parasite form. We postulate that intrinsically uncoupled respiration provided by the GPSh-TAO system acts as a preventive antioxidant defense by limiting mitochondrial superoxide production and complementing the NADPH-dependent scavenging antioxidant defenses to maintain redox balance. Given the uncoupled nature of the GPSh-TAO system, BSF avoids cell death processes by maintaining mitochondrial protonmotive force through the reversal of ATP synthase activity using the ATP generated by glycolysis. This unique “metabolic design” in BSF has no biological parallel outside of trypanosomatids and highlights the enormous diversity of the parasite mitochondrial processes to adapt to distinct environments. <br>  +

::: <small>Version 2 ('''v2''') '''2022-07-07''' [https://wiki.oroboros.at/images/5/54/Alencar_2022_MitoFit.pdf doi:10.26124/mitofit:2022-0009.v2]</small> ::: <small>Version 1 (v1) 2022-04-07 [https://wiki.oroboros.at/images/archive/5/54/20220707123437%21Alencar_2022_MitoFit.pdf doi:10.26124/mitofit:2022-0009.v1] - [https://wiki.oroboros.at/index.php/File:Alencar_2022_MitoFit.pdf »Link to all versions«]</small> [[Oliveira 2022 Abstract Bioblast]]: The parasite ''Trypanosoma brucei'' is the causative agent of sleeping sickness and involves an insect vector and a mammalian host through its complex life-cycle. ''T. brucei'' mammalian bloodstream forms (BSF) exhibit unique metabolic features including: ''i)'' reduced expression and activity of mitochondrial enzymes; ''ii)'' respiration mediated by the glycerol phosphate shuttle (GPSh) and the ''Trypanosome'' alternative oxidase (TAO) that is intrinsically uncoupled from generation of mitochondrial membrane potential; ''iii)'' maintenance of mitochondrial membrane potential by ATP hydrolysis through the reversal of F1Fo ATP synthase activity; ''iv)'' strong reliance on glycolysis to meet their energy demands; ''v)'' high susceptibility to oxidants. Here, we critically review the main metabolic features of BSF and provide a hypothesis to explain the unusual metabolic network and its biological significance for this parasite form. We postulate that intrinsically uncoupled respiration provided by GPSh-TAO system would act as a preventive antioxidant defense by limiting mitochondrial superoxide production and complementing the NADPH-dependent scavenging antioxidant defenses to maintain parasite redox balance. Given the uncoupled nature of the GPSh-TAO system, BSF would avoid programmed cell death processes by maintaining mitochondrial membrane potential through the reversal of ATP synthase activity using the ATP generated by glycolysis. This unique “metabolic design” in BSF has no biological parallel outside of Trypanosomatids and highlights the enormous diversity of the parasite mitochondrial processes to adapt to distinct environments.   

Previous work suggests that Dihydroorotate dehydrogenase (DHODH) inhibition via teriflunomide (TERI) may provide protection in multiple disease models. To date, little is known about the effect of TERI on the heart. This study was performed to assess the potential effects of TERI on cardiac ischemia reperfusion injury. Male and female rat hearts were subjected to global ischemia (25 min) and reperfusion (120 min) on a Langendorff apparatus. Hearts were given either DMSO (VEH) or teriflunomide (TERI) for 5 min prior to induction of ischemia and during the reperfusion period. Left ventricular pressure, ECG, coronary flow, and infarct size were determined using established methods. Mitochondrial respiration was assessed via respirometry. Perfusion of hearts with TERI led to no acute effects in any values measured across 500 pM-50 nM doses. However, following ischemia-reperfusion injury, we found that 50 nM TERI-treated hearts had an increase in myocardial infarction (p < 0.001). In 50 nM TERI-treated hearts, we also observed a marked increase in the severity of contracture (p < 0.001) at an earlier time-point (p = 0.004), as well as reductions in coronary flow (p = 0.037), left ventricular pressure development (p = 0.025), and the rate-pressure product (p = 0.008). No differences in mitochondrial respiration were observed with 50 nM TERI treatment (p = 0.24-0.87). This study suggests that treatment with TERI leads to more negative outcomes following cardiac ischemia reperfusion, and administration of TERI to at-risk populations should receive special considerations.  +

Migratory species travelling long distances between habitats to spawn or feed are well adapted to optimize their swimming economy. However, human activities, such as river regulation, represent potential threats to fish migration by changing environmental parameters that will have impact on their metabolism. The main objective of this study was to evaluate the changes in the swimming energetics of a salmonid species, Atlantic salmon (''Salmo salar L.''), caused by short-term temperature variations that usually result from the operation of hydroelectrical dams. Intermittent flow respirometry in swim tunnels allows to obtain high resolution data on oxygen consumption of swimming fish which can reflect aerobic and anaerobic metabolism. This method was used to compare the metabolic rates of oxygen consumption before, during and after sudden thermal change. Control (no temperature variation) and experimental (temperature variation of approximately 4°C in 1 h) swimming trials were conducted to achieve the following objectives: (i) quantify the variations in oxygen consumption associated with abrupt temperature decrease, and (ii) assess if the tested fish return quickly to initial oxygen consumption rates. Main results revealed that Atlantic salmon smolts show a strong response to sudden temperature variation, significantly reducing the oxygen consumption rate up to a seven-fold change. Fish quickly returned to initial swimming costs shortly after reestablishment of temperature values. Results from this study can be used to evaluate the species-specific effects of the applied operation modes by hydroelectrical dams and to increase the success of conservation and management actions directed to fish species inhabiting regulated rivers.  +

Obesity is a health problem affecting more than 40% of US adults and 13% of the global population. Anti-obesity treatments including diet, exercise, surgery and pharmacotherapies have so far failed to reverse obesity incidence. Herein, we target obesity with a pharmacotherapeutic approach that decreases caloric efficiency by mitochondrial uncoupling. We show that a recently identified mitochondrial uncoupler BAM15 is orally bioavailable, increases nutrient oxidation, and decreases body fat mass without altering food intake, lean body mass, body temperature, or biochemical and haematological markers of toxicity. BAM15 decreases hepatic fat, decreases inflammatory lipids, and has strong antioxidant effects. Hyperinsulinemic-euglycemic clamp studies show that BAM15 improves insulin sensitivity in multiple tissue types. Collectively, these data demonstrate that pharmacologic mitochondrial uncoupling with BAM15 has powerful anti-obesity and insulin sensitizing effects without compromising lean mass or affecting food intake.  +

Cardiovascular diseases (CVDs) are devastating disorders and the leading cause of mortality worldwide. The pathophysiology of cardiovascular diseases is complex and multifactorial and, in the past years, mitochondrial dysfunction and excessive production of reactive oxygen species (ROS) have gained growing attention. Indeed, CVDs can be considered as a systemic alteration, and understanding the eventual implication of circulating blood cells peripheral blood mononuclear cells (PBMCs) and or platelets, and particularly their mitochondrial function, ROS production, and mitochondrial DNA (mtDNA) releases in patients with cardiac impairments, appears worthwhile. Interestingly, reports consistently demonstrate a reduced mitochondrial respiratory chain oxidative capacity related to the degree of CVD severity and to an increased ROS production by PBMCs. Further, circulating mtDNA level was generally modified in such patients. These data are critical steps in term of cardiac disease comprehension and further studies are warranted to challenge the possible adjunct of PBMCs' and platelets' mitochondrial dysfunction, oxidative stress, and circulating mtDNA as biomarkers of CVD diagnosis and prognosis. This new approach might also allow further interesting therapeutic developments.  +

Salicylates from plant sources have been used for centuries by different cultures to treat a variety of ailments such as inflammation, fever and pain. A chemical derivative of salicylic acid, aspirin, was synthesised and mass produced by the end of the 19th century and is one of the most widely used drugs in the world. Its cardioprotective properties are well established; however, recent evidence shows that it can also act as a chemopreventive agent. Its antithrombotic and anti-inflammatory actions occur through the inhibition of cyclooxygenases. The precise mechanisms leading to its anticancer effects are not clearly established, although multiple mechanisms affecting enzyme activity, transcription factors, cellular signalling and mitochondrial functions have been proposed. This review presents a brief account of the major COX-dependent and independent pathways described in connection with aspirin's anticancer effects. Aspirin's unique ability to acetylate biomolecules besides COX has not been thoroughly investigated nor have all the targets of its primary metabolite, salicylic acid been identified. Recent reports on the ability of aspirin to acetylate multiple cellular proteins warrant a comprehensive study to investigate the role of this posttranslational modification in its anticancer effects. In this review, we also raise the intriguing possibility that aspirin may interact and acetylate cellular molecules such as RNA, and metabolites such as CoA, leading to a change in their function. Research in this area will provide a greater understanding of the mechanisms of action of this drug.  +

AlgaEurope 2020, Virtual Event, 2020, NextGen-O2k  +

AlgaEurope 2022, Rome, IT, 2022  +

[[File:01.jpg|right|150px|Sameh Ali]] Many neurodegenerative, cardiovascular, cancer, and psychological disorders are known to involve mitochondrial dysfunction and deregulated levels of reactive oxygen species. Aging is associated with a sustained increase in superoxide radical levels, which is associated with a progressive decline in cognitive function and increased prevalence of neurodegeneration. Mitochondria were identified as one source of oxidant production in brain during aging, but several recent studies suggest that an alternative, extra-mitochondrial source of superoxide may also be important to aging-associated pathologic phenotype. In this presentation I will briefly discuss some of our contributions to the field including our studies on the dynamics of mitochondrial superoxide production, and our recent discovery that the superoxide-producing enzyme NADPH-oxidase-2 (Nox2) is induced during aging and remain constitutively active in neurons and synaptosomes from aged brain and from schizophrenia mouse model. Finally, I’ll present our progress in establishing the Center for Aging and Associated Diseases (CAAD) as part of the newly founded Zewail City of Science and Technology, the Egyptian National Project of Scientific Renaissance. In CAAD, we are focusing primarily on establishing a state-of-the-art facility to study diseases in relevance to the Egyptian people. In one of CAAD’s core facilities, the Oroboros® O2k-MultiSensor system will be combined with the Seahorse XF24 and the Magnettech MS400 EPR spectrometer to study mitochondrial dynamics in the context of aging, metabolic, cardiovascular, and neurodegenerative diseases. # [http://www.ncbi.nlm.nih.gov/pubmed?term=Ali%2C%20SS%2C%20Marcondes%2C%20MC%2C%20Bajova%2C%20H%2C%20and%20Conti%2C%20B Ali SS, Marcondes MC, Bajova H, Dugan LL, Conti B (2010) Metabolic depression and increased reactive oxygen species production by isolated mitochondria at moderately lower temperatures J Biol Chem 285: 32522-32528. Open Access] # [http://www.ncbi.nlm.nih.gov/pubmed?term=Initial%20evidence%20linking%20synaptic%20superoxide%20production%20with%20poor%20short-term%20memory%20in%20aged%20mice Ali SS, Young JW, Wallace CK, Gresack J, Jeste DV, Geyer MA, Dugan LL, Risbrough VB (2011) Initial evidence linking synaptic superoxide production with poor short-term memory in aged mice. Brain Res 1368: 65-70. Open Access] # [http://www.ncbi.nlm.nih.gov/pubmed?term=Mitochondria-localized%20caveolin%20in%20adaptation%20tro%20cellular%20stress%20and%20injury Fridolfsson HN, Kawaraguchi Y, Ali SS, Panneerselvam M, Niesman IR, Finley JC, Kellerhals SE, Migita MY, Okada H, Moreno AL, Jennings M, Kidd MW, Bonds JA, Balijepalli RC, Ross RS, Patel PM, Miyanohara A, Chen Q, Lesnefsky EJ, Head BP, Roth DM, Insel PA, Patel HH (2012) Mitochondria-localized caveolin in adaptation to cellular stress and injury. FASEB J 26: 4637-4649. Open Access]  

Although originally defined as harmful byproducts of aerobic metabolism, reactive oxygen species (ROS) are currently believed to play a critical role in downstream signaling, which regulates protein kinases, phosphatases, transcription factors and ion transport channels. However, mechanisms by which ROS is responsively produced, sensed and translated in cellular domains, especially neurons, remain elusive. Recently, NADPH oxidase (NOX), which is a multimeric enzyme that catalyzes the production of superoxide (O2•) from O2 and NADPH and was originally identified in neutrophils as essential for the host response respiratory burst, has been shown to localize in the brain. The unexpected presence of NOX in neurons has led to the idea that NOX-induced ROS are important in non-host defense contexts; e.g. intracellular and intercellular redox signaling. In previous works, we showed that NOX is actively producing O2• in the brain and might therefore be an important element that influences redox homeostasis in health, disease, and aging. Questions on specific connections between NOX activation and neuronal dysfunctions remain open for exploration by unconventional experimental approaches capable of probing the implications of in vivo NOX assembly and activation. Here, we studied oxygen-consuming, superoxide-producing NOX basal as well as induced activities in synaptosomes. Isolated synaptosomes (severed nerve terminals) are studied because they contain all necessary components of a functional neuronal environment including ion channels, receptors, and mitochondria. We demonstrate the ability of the Oroboros Oxygraph-2k, in parallel with spin-trapping/labeling electron paramagnetic resonance (EPR) techniques, to study sources and dynamics of ROS in synaptosomes. To the best of our knowledge, this is the first time that the Oroboros system has been employed to quantify NOX activity in synaptosomes.  +

Gender-specific differences in mitochondrial function and free radical homeostasis are consistently reported in the context of aging and associated deficits. However, little is known about the gender-related roles of these parameters in the pathogenesis of neurological and cardiovascular disorders that occur early in life. Aim: To test the hypothesis that gender disparity in mitochondria function and ROS homeostasis starts early in life and hence can be implicated in sexual dimorphism in some cardiac as well as neurological disorders. Approach: We investigated heart and brain mitochondrial respiratory function in young (2-4 months) male and female wild-type C57BL6J mice, by high-resolution respirometry. Parallel productions of ROS by respiring mitochondria or active NADPH oxidases (NOXs) were also assessed using high-resolution oxymetry, fluorescence assays, and electron paramagnetic resonance (EPR) spin trapping techniques. Results: Although mitochondrial respiratory activity in the heart did not significantly vary between genders, female brains exhibited enhanced activity during state 3, state 4, and maximally uncoupled respiration. This was associated with lower rates of hydrogen peroxide production in female cardiac and brain tissues. Furthermore, no gender differences have been detected in Nox2 and Nox4 proteins or activities in brain homogenate or freshly isolated synaptosomes. However, a strong trend of increased EPR-detected NOX-superoxide in male synaptosomes hinted at gender-specific discrepancy in antioxidant enzymes. Indeed, we found that superoxide dismutase (SOD) activity was higher in female brains using two independent approaches. Conclusion: Taken together, our results indicate that gender differences in mitochondrial bioenergetics and ROS production occur at young age, and that differences in superoxide dismutation capacity may be primarily responsible for gender differences in ROS homeostasis. These findings may eventually assist in the understanding of sexual dimorphism in some disorders that occur early in life.  

Mitochondrial dysfunction and oxidative stress are proposed as key elements in the pathogenesis of aging, as well as neurological and cardiovascular disorders that occur early in life. Sex differences in free radical homeostasis upon aging have been extensively studied. However, little is known about gender differences in mitochondrial function and dynamics of ROS sources that may develop in young ages and hence contribute to sexual dimorphism in some disorders that occur early in life. We investigated heart and brain mitochondrial respiratory function and ROS production in young (2-5 months) male and female wild-type C57BL6 mice using the Oroboros Oxygraph-2k. Mitochondrial respiratory activity in heart did not significantly differ between genders. However, female brains had an enhanced mitochondrial respiratory activity during state 3, state 4, and maximally uncoupled respiration as compared to male brains. This respiratory activity observed in mitochondria from female heart and brain was associated with lower rates of hydrogen peroxide production in cardiac and neuronal female mitochondria as compared to male. By using two different approaches, we also found that superoxide dismutase (Sod) activity was higher in female brains, suggesting that enhanced antioxidant defenses in female brains contribute to gender differences in ROS levels. Neither protein expression of NADPH oxidases (Nox2 & Nox4) in brain homogenate or synaptosomes, nor the Oroboros determined activity of these enzymes changed between genders. Paradoxically, when Nox-superoxide was assessed in synaptosomes using spin trapping electron paramagnetic resonance spectroscopy, males exhibited higher activity. We conclude that gender differences in mitochondrial function and ROS production occur in young age, and that differences in antioxidant buffering capacity between genders may be primarily responsible for gender differences in brain ROS homeostasis.  +

[[Image:MITOEAGLE-logo.jpg|left|100px|link=http://www.mitoglobal.org/index.php/MITOEAGLE|COST Action MitoEAGLE]] Cancer transformations profoundly alters cellular metabolism by increasing glucose consumption via glycolysis to support tumorigenesis. Triple-negative breast cancer (TNBC) subtype is among the most aggressive cancers with the worst prognosis and least therapeutic targetability while being more likely to spread and recur. Here we confirm that relative to ER-positive cells (MCF7), TNBC cells (MBA-MD-231) rely more on glycolysis thus providing rationale to target these cells with glycolytic inhibitors. Indeed, iodoacetate (IA), an effective GAPDH inhibitor, caused about 70% drop in MDA-MB-231 cell viability at 20 μM while 40 μM IA was needed to decrease MCF7 cell viability only by 30% within 4 hours of treatment. However, the triple negative cells showed strong ability to recover after 24 h whereas MCF7 cells were completely eliminated at concentrations < 10 μM. This resilient TNBC cell population showed lower apoptotic markers, moderately lowered ROS, and significantly greater count of cells with active mitochondria. To understand the mechanism of survival we studied metabolic modulations associated with acute and extended treatment with IA. Our results highlight an interplay between PARP and mitochondrial oxidative phosphorylation in TNBC that comes into play in response to glycolytic disruption. In the light of these findings, we suggest that combined treatment with PARP and mitochondrial inhibitors may provide novel therapeutic strategy against TNBC.  +

[[Image:MITOEAGLE-logo.jpg|left|100px|link=http://www.mitoeagle.org/index.php/MitoEAGLE|COST Action MitoEAGLE]] Targeting characteristic metabolic modes to drain bioenergetics in cancer cells has recently gained attention. To increase the potential of this strategy, drugs must be drastic inhibitors of all metabolic pathways in cancer cell subpopulations, and importantly, be targeting malignant cells selectively. We exploited enhanced expression of asialoglycoprotein receptors on human hepatocellular carcinoma HepG2 cell membrane for specific delivery of an effective metabolic inhibitor loaded in nanoparticles conjugated with galactosylated chains as recognition termini. Submicromoles of iodoacetate-loaded nanoparticles (NIA) were sufficient to completely disrupt glycolytic as well as mitochondrial metabolism, causing substantial cytotoxicity of HepG2 cells within 4 h. To identify the mechanism of cell death by NIA, we performed extensive metabolic investigations of mitochondria stress in intact-attached or permeabilized-suspended HepG2 cells as well as on isolated mitochondria. Metabolic, flow cytometric, and molecular studies provided converging evidence that NIA triggers complete cell death through mitochondrial ROS-mediated apoptosis induction concomitant with bioenergetic deprivation in HepG2 and HuH-7 but not in normal WI-38 cells. Imaging studies confirmed lower uptake of NIA by normal cells and their mitochondria relative to cancer cells which highlight the targetability of cancer cell mitochondria by the current combination. Overall, our results revealing the ability of relatively low NIA concentrations to completely disrupt various metabolic pathways that are crucial for proliferating as well as resilient cancer cells provide a new treatment approach via nanoparticle-assisted metabolic interventions.  +

[[Image:MITOEAGLE-logo.jpg|left|100px|link=http://www.mitoglobal.org/index.php/MITOEAGLE|COST Action MitoEAGLE]]  +

Nucleotides are the foundational elements of life. Proliferative cells acquire nutrients for energy production and the synthesis of macromolecules, including proteins, lipids, and nucleic acids. Nucleotides are continuously replenished through the activation of the nucleotide synthesis pathways. Despite the importance of nucleotides in cell physiology, there is still much to learn about how the purine and pyrimidine synthesis pathways are regulated in response to intracellular and exogenous signals. Over the past decade, evidence has emerged that several signaling pathways [Akt, mechanistic target of rapamycin complex I (mTORC1), RAS, TP53, and Hippo-Yes-associated protein (YAP) signaling] alter nucleotide synthesis activity and influence cell function. Here, we examine the mechanisms by which these signaling networks affect de novo nucleotide synthesis in mammalian cells. We also discuss how these molecular links can be targeted in diseases such as cancers and immune disorders.  +

Statin myopathy is linked to disturbances in mitochondrial function and exercise intolerance. To determine whether differences exist in exercise performance, muscle function, and muscle mitochondrial oxidative capacity and content between symptomatic and asymptomatic statin users, and control subjects. Cross-sectional study. Department of Physiology, Radboud University Medical Center. Long-term symptomatic and asymptomatic statin users, and control subjects (n = 10 per group). Maximal incremental cycling tests, involuntary electrically stimulated isometric quadriceps-muscle contractions, and biopsy of vastus lateralis muscle. Maximal exercise capacity, substrate use during exercise, muscle function, and mitochondrial energy metabolism. Peak oxygen uptake, maximal work load, and ventilatory efficiency were comparable between groups, but both statin groups had a depressed anaerobic threshold compared with the control group (P = 0.01). Muscle relaxation time was prolonged in both statin groups compared with the control group and rate of maximal force rise was decreased (P_time×group < 0.001 for both measures). Mitochondrial activity of complexes II and IV was lower in symptomatic statin users than control subjects and tended to be lower for complex (C) III (CII: P = 0.03; CIII: P = 0.05; CIV: P = 0.04). Mitochondrial content tended to be lower in both statin groups than in control subjects. Statin use attenuated substrate use during maximal exercise performance, induced muscle fatigue during repeated muscle contractions, and decreased muscle mitochondrial oxidative capacity. This suggests disturbances in mitochondrial oxidative capacity occur with statin use even in patients without statin-induced muscle complaints.  +

Mitochondria influence cardiac electrophysiology through energy- and redox-sensitive ion channels in the sarcolemma, with the collapse of energetics believed to be centrally involved in arrhythmogenesis. This study was conducted to determine if preservation of mitochondrial membrane potential (ΔΨm) contributes to the anti-arrhythmic effect of exercise. We determined the effects of exercise on cardiac mitochondria by utilizing a combination of perfused hearts, isolated myocytes, and isolated mitochondria exposed to metabolic challenge. Hearts from sedentary (Sed) and exercised (Ex; 10 days of treadmill running) Sprague Dawley rats were perfused on a two-photon microscope stage for simultaneous measurement of ΔΨm and ECG. Following ischemia-reperfusion, the collapse of ΔΨm was commensurate with the onset of arrhythmia. Exercise preserved ΔΨm and decreased the incidence of fibrillation/tachycardia (P<0.05). Our findings in intact hearts were corroborated in isolated myocytes exposed to ''in vitro'' hypoxia-reoxygenation, with Ex demonstrating enhanced redox control and sustained ΔΨm during reoxygenation. Finally, we induced anoxia-reoxygenation in isolated mitochondria using high-resolution respirometry with simultaneous measurement of respiration and H₂O₂. Ex mitochondria sustained respiration with lower rates of H₂O₂ emission compared to Sed. Exercise helps sustain post-ischemic mitochondrial bioenergetics, leading to preserved ∆Ψm and protection against reperfusion arrhythmia. The reduction of fatal ventricular arrhythmias through exercise-induced mitochondrial adaptations indicates that mitochondrial therapeutics may be an effective target for the treatment of heart disease. Copyright © 2015, American Journal of Physiology - Heart and Circulatory Physiology.  +

Mitochondrial dysfunction contributes to cardiac pathologies. Barriers to new therapies include an incomplete understanding of underlying molecular culprits and a lack of effective mitochondria-targeted medicines. Here, we test the hypothesis that the cardiolipin-binding peptide elamipretide, a clinical-stage compound under investigation for diseases of mitochondrial dysfunction, mitigates impairments in mitochondrial structure-function observed after rat cardiac ischemia-reperfusion. Respirometry with permeabilized ventricular fibers indicates that ischemia-reperfusion induced decrements in the activity of complexes I, II, and IV are alleviated with elamipretide. Serial block face scanning electron microscopy used to create 3D reconstructions of cristae ultrastructure reveals that disease-induced fragmentation of cristae networks are improved with elamipretide. Mass spectrometry shows elamipretide did not protect against the reduction of cardiolipin concentration after ischemia-reperfusion. Finally, elamipretide improves biophysical properties of biomimetic membranes by aggregating cardiolipin. The data suggest mitochondrial structure-function are interdependent and demonstrate elamipretide targets mitochondrial membranes to sustain cristae networks and improve bioenergetic function.  +

Mitochondria are metabolic hubs, with many diseases found to have altered metabolism and mitochondrial dysfunction, such as ischaemia-reperfusion injury. A detailed understanding of the metabolic changes in different cellular pools would aid diagnosis and treatment. However, the current methods of mitochondrial isolation are too slow to provide a snapshot of purely mitochondrial metabolism, meaning that current metabolic data is only from whole cell. This project has developed and used a novel technique to rapidly isolate mitochondria from tissue by density centrifugation through silicone oil, with a view to assess the mitochondrial metabolic changes during ischaemia-reperfusion injury. This method has minimal cytosolic contamination and is completed in under 5 minutes, and mass spectroscopy analysis has shown enrichment of mitochondrial metabolites. Seahorse and Oroboros analysis have shown that the mitochondria are functional and capable of coupled respiration. Data is presented on how the method optimisation was analysed and developed. This largely reduced time frame gives the advantage over other methods to enable the study of metabolism in mitochondria.  +

Mitochondrial cholesterol trafficking, from the outer mitochondrial membrane to sterol 27-hydroxylase located on the inner mitochondrial membrane, facilitates generation of endogenous oxysterol ligands, capable of activating Liver X receptor (LXR) responsive genes such as ATP binding cassette transporters (ABCA1, ABCG1, ABCG4) which orchestrate cholesterol efflux from cells (1,2).  +

Our preliminary study shows that cinnamaldehyde (CA) could protect against intestinal ischemia/reperfusion (I/R) injuries, in which p53 and NF-κB p65 play a synergistic role. In this study, we conducted ''in vivo'' and ''in vitro'' experiments to verify this proposal. SD rats were pretreated with CA (10 or 40 mg · kg^-1 · d^-1, ig) for 3 days, then subjected to 1 h mesenteric ischemia followed by 2 h reperfusion. CA pretreatment dose-dependently ameliorated morphological damage and reduced inflammation evidenced by decreased TNF-α, IL-1β, and IL-6 levels and MPO activity in I/R-treated intestinal tissues. CA pretreatment also attenuated oxidative stress through restoring SOD, GSH, LDH, and MDA levels in I/R-treated intestinal tissues. Furthermore, CA pretreatment significantly reduced the expression of inflammation/apoptosis-related NF-κB p65, IKKβ, IK-α, and NF-κB p50, and downregulated apoptotic protein expression including p53, Bax, caspase-9 and caspase-3, and restoring Bcl-2, in I/R-treated intestinal tissues. We pretreated IEC-6 cells in vitro with CA for 24 h, followed by 4 h hypoxia and 3 h reoxygenation (H/R) incubation. Pretreatment with CA (3.125, 6.25, and 12.5 μmol · L^-1) significantly reversed H/R-induced reduction of IEC-6 cell viability. CA pretreatment significantly suppressed oxidative stress, NF-κB activation and apoptosis in H/R-treated IEC-6 cells. Moreover, CA pretreatment significantly reversed mitochondrial dysfunction in H/R-treated IEC-6 cells. CA pretreatment inhibited the nuclear translocation of p53 and NF-κB p65 in H/R-treated IEC-6 cells. Double knockdown or overexpression of p53 and NF-κB p65 caused a synergistic reduction or elevation of p53 compared with knockdown or overexpression of p53 or NF-κB p65 alone. In H/R-treated IEC-6 cells with double knockdown or overexpression of NF-κB p65 and p53, CA pretreatment caused neither further decrease nor increase of NF-κB p65 or p53 expression, suggesting that CA-induced synergistic inhibition on both NF-κB and p53 played a key role in ameliorating intestinal I/R injuries. Finally, we used immunoprecipitation assay to demonstrate an interaction between p53 and NF-κB p65, showing the basis for CA-induced synergistic inhibition. Our results provide valuable information for further studies.  

The steroid Na⁺/K⁺ ATPase (NKA) blocker ouabain has been shown to exhibit pro-apoptotic effects in various cell systems; however, the mechanism involved in those effects is unclear. Here, we have demonstrated that incubation of HeLa cells during 24h with nanomolar concentrations of ouabain or digoxin causes apoptotic death of 30-50% of the cells. Ouabain caused the activation of caspases-3/7 and -9; however, caspase-8 was unaffected. The fact that compound Z-LEHD-FMK reduced both apoptosis and caspase-9 activation elicited by ouabain, suggest a mitochondrially-mediated pathway. This was strengthened by the fact that ouabain caused ATP depletion and the release of mitochondrial cytochrome c into the cytosol. Furthermore, upon ouabain treatment mitochondrial disruption and redistribution into the cytosol were observed. A mitochondrial site of action for ouabain was further corroborated by tight co-localisation of fluorescent ouabain with mitochondria. Finally, in ouabain-treated cells the histamine-elicited elevation of cytosolic Ca²⁺ concentration ([Ca²⁺]c) suggests an additional effect on the endoplasmic reticulum (ER) leading to Ca²⁺ store depletion. We conclude that fluorescent ouabain is taken up and tightly co-localises with mitochondria of HeLa cells. This indicates that apoptosis may be triggered by a direct action of ouabain on mitochondria. Copyright © 2013 Elsevier Ltd. All rights reserved.  +

Palmitoleic acid is a monounsaturated n-7 fatty acid (16:1n7), produced and released by adipocytes, that has been shown to enhance whole body glucose disposal, to attenuate high-fat-fed mice hepatic steatosis, to protect pancreatic beta-cells from palmitic acid-induced death and to improve circulating lipid profile in both rodents and humans. Our group has recently found strong evidence that 16:1n7 is an important positive modulator of white adipocyte lipolysis and the content of the major lipases ATGL and HSL through a PPAR alpha-dependent mechanism ''in vitro'' and ''in vivo''. To study the correlation of the previously described effects of 16:1n7 in white adipose tissue with mitochondrial function, we performed oxygen consumption experiments using the Oroboros Oxygraph-2k. Our results show that both acute and chronic treatments with 16:1n7 enhanced basal oxygen consumption in 3T3-L1 adipocytes by 7.6% and 12.8%, respectively. Experiments were also carried out to test whether lipolysis and respiration enhancement by palmitoleic acid are linked to improved mitochondrial fatty acid oxidation (FAO) and/or uncoupling. We observed an increase (~30%) in FAO by the adipocytes treated with C16:1n7. Taken together, our data suggest that the palmitoleic acid, by concerted action of stimulated lipolysis, mitochondrial FAO and oxygen consumption may contribute to enhance white adipocytes energy expenditure.  +

Mitochondria are double-membrane-bound organelles that are present in all nucleated eukaryotic cells and are responsible for the production of cellular energy in the form of ATP. Mitochondrial function is under dual genetic control - the 16.6-kb mitochondrial genome, with only 37 genes, and the nuclear genome, which encodes the remaining ∼1300 proteins of the mitoproteome. Mitochondrial dysfunction can arise because of defects in either mitochondrial DNA or nuclear mitochondrial genes, and can present in childhood or adulthood in association with vast clinical heterogeneity, with symptoms affecting a single organ or tissue, or multisystem involvement. There is no cure for mitochondrial disease for the vast majority of mitochondrial disease patients, and a genetic diagnosis is therefore crucial for genetic counselling and recurrence risk calculation, and can impact on the clinical management of affected patients. Next-generation sequencing strategies are proving pivotal in the discovery of new disease genes and the diagnosis of clinically affected patients; mutations in >250 genes have now been shown to cause mitochondrial disease, and the biochemical, histochemical, immunocytochemical and neuropathological characterization of these patients has led to improved diagnostic testing strategies and novel diagnostic techniques. This review focuses on the current genetic landscape associated with mitochondrial disease, before focusing on advances in studying associated mitochondrial pathology in two, clinically relevant organs - skeletal muscle and brain. © 2016 The Authors. The Journal of Pathology published by John Wiley & Sons Ltd on behalf of Pathological Society of Great Britain and Ireland.  +

Isolated complex I deficiency is a common biochemical phenotype observed in pediatric mitochondrial disease and often arises as a consequence of pathogenic variants affecting one of the ∼65 genes encoding the complex I structural subunits or assembly factors. Such genetic heterogeneity means that application of next-generation sequencing technologies to undiagnosed cohorts has been a catalyst for genetic diagnosis and gene-disease associations. We describe the clinical and molecular genetic investigations of four unrelated children who presented with neuroradiological findings and/or elevated lactate levels, highly suggestive of an underlying mitochondrial diagnosis. Next-generation sequencing identified bi-allelic variants in NDUFA6, encoding a 15 kDa LYR-motif-containing complex I subunit that forms part of the Q-module. Functional investigations using subjects' fibroblast cell lines demonstrated complex I assembly defects, which were characterized in detail by mass-spectrometry-based complexome profiling. This confirmed a marked reduction in incorporated NDUFA6 and a concomitant reduction in other Q-module subunits, including NDUFAB1, NDUFA7, and NDUFA12. Lentiviral transduction of subjects' fibroblasts showed normalization of complex I. These data also support supercomplex formation, whereby the ∼830 kDa complex I intermediate (consisting of the P- and Q-modules) is in complex with assembled complex III and IV holoenzymes despite lacking the N-module. Interestingly, RNA-sequencing data provided evidence that the consensus RefSeq accession number does not correspond to the predominant transcript in clinically relevant tissues, prompting revision of the NDUFA6 RefSeq transcript and highlighting not only the importance of thorough variant interpretation but also the assessment of appropriate transcripts for analysis.  +

Leigh syndrome is one of the most common neurological phenotypes observed in pediatric mitochondrial disease presentations. It is characterized by symmetrical lesions found on neuroimaging in the basal ganglia, thalamus, and brainstem and by a loss of motor skills and delayed developmental milestones. Genetic diagnosis of Leigh syndrome is complicated on account of the vast genetic heterogeneity with >75 candidate disease-associated genes having been reported to date. Candidate genes are still emerging, being identified when "omics" tools (genomics, proteomics, and transcriptomics) are applied to manipulated cell lines and cohorts of clinically characterized individuals who lack a genetic diagnosis. NDUFAF8 is one such protein; it has been found to interact with the well-characterized complex I (CI) assembly factor NDUFAF5 in a large-scale protein-protein interaction screen. Diagnostic next-generation sequencing has identified three unrelated pediatric subjects, each with a clinical diagnosis of Leigh syndrome, who harbor bi-allelic pathogenic variants in NDUFAF8. These variants include a recurrent splicing variant that was initially overlooked due to its deep-intronic location. Subject fibroblasts were found to express a complex I deficiency, and lentiviral transduction with wild-type NDUFAF8-cDNA ameliorated both the assembly defect and the biochemical deficiency. Complexome profiling of subject fibroblasts demonstrated a complex I assembly defect, and the stalled assembly intermediates corroborate the role of NDUFAF8 in early complex I assembly. This report serves to expand the genetic heterogeneity associated with Leigh syndrome and to validate the clinical utility of orphan protein characterization. We also highlight the importance of evaluating intronic sequence when a single, definitively pathogenic variant is identified during diagnostic testing. <small>Copyright © 2019 The Author(s). Published by Elsevier Inc. All rights reserved.</small>  +

Metabolism in cancer cells is rewired to generate sufficient energy equivalents and anabolic precursors to support high proliferative activity. Within the context of these competing drives aerobic glycolysis is inefficient for the cancer cellular energy economy. Therefore, many cancer types, including colon cancer, reprogram mitochondria-dependent processes to fulfill their elevated energy demands. Elevated glycolysis underlying the Warburg effect is an established signature of cancer metabolism. However, there are a growing number of studies that show that mitochondria remain highly oxidative under glycolytic conditions. We hypothesized that activities of glycolysis and oxidative phosphorylation are coordinated to maintain redox compartmentalization. We investigated the role of mitochondria-associated malate-aspartate and lactate shuttles in colon cancer cells as potential regulators that couple aerobic glycolysis and oxidative phosphorylation. We demonstrated that the malate-aspartate shuttle exerts control over NAD⁺/NADH homeostasis to maintain activity of mitochondrial lactate dehydrogenase and to enable aerobic oxidation of glycolytic l-lactate in mitochondria. The elevated glycolysis in cancer cells is proposed to be one of the mechanisms acquired to accelerate oxidative phosphorylation. <small>© 2019 Wiley Periodicals, Inc.</small>  +

The protoplasm is a colony of bioblasts. Microorganisms and granula are at an equivalent level and represent elementary organisms, which are found wherever living forces are acting, thus we want to describe them by the common term bioblasts. In the bioblast, that morphological unit of living matter appears to be found.  +

New molecular hybrids were synthesized by combining tetrahydroquinoline (THQ) and isoxazole (ISX) scaffolds, in search for chemical structures with improved pharmacological properties. Our tetrahydroquinoline (THQ) and isoxazole (ISX) hybrids differ in the X and Y substituents: FM53 (X = H; Y= H), FM49 (X = CH₃; Y= OCH₃), FM50 (X = Cl; Y= H) and FM48 (X = Cl; Y= OCH₃). Aiming at exploring their bioactivity in liver cancer cells, in this paper we report the effect of four THQ-ISX hybrids on viability, respiration and oxidative stress in Hep-G2 human hepatoma cells. In addition, we measured the alterations induced by these compounds on oxygen uptake and respiratory chain enzymes in isolated mitochondria. Cell viability assay indicated that these THQ-ISX hybrids displayed antiproliferative activity on Hep-G2 cells. Among these, FM50 (IC₅₀ = 5.2 ± 1.9 μM) and FM53 (IC₅₀ = 6.8 ± 0.7 μM) had the highest cytotoxicity. These four hybrids also inhibited the Hep-G2 cells respiration in the uncoupled state, with FM50 decreasing all respiratory states (basal, leak, uncoupled). While only FM49 and FM53 altered the Hep-G2 cells redox function. In terms of mitochondrial bioenergetics, THQ-ISX hybrids decreased the oxygen consumption in state 3 (via complex I and II), and also inhibited NADH oxidase and NADH cytochrome c reductase enzyme activities. In these experiments, the structural homologues FM50 and FM53 had a remarkable inhibitory effect (∼50%) with respect to FM49 and FM48. These results show that THQ-ISX hybrids are promising compounds for hepatoma cancer treatment and that the phenyl substituent (Y= H) in the ISX scaffold intensifies both, the cytotoxicity in Hep-G2 cells and, inhibition of electron transport through complex I of the mitochondrial respiratory chain. <small>Copyright © 2019. Published by Elsevier B.V.</small>  +

The uricosuric agent probenecid is co-administered with the dopaminergic neurotoxin MPTP to produce a chronic mouse model of Parkinson's disease. It has been proposed that probenecid serves to elevate concentrations of MPTP in the brain by reducing renal elimination of the toxin. However, this mechanism has never been formally demonstrated to date and is questioned by our previous data showing that intracerebral concentrations of MPP+ , the active metabolite of MPTP, are not modified by co-injection of probenecid. In this study, we investigated the potentiating effects of probenecid ''in vivo'' and ''in vitro'' arguing against the possibility of altered metabolism or impaired renal elimination of MPTP. We find that probenecid (i) is toxic in itself to several neuronal populations apart from dopaminergic neurons, and (ii) that it also potentiates the effects of other mitochondrial complex I inhibitors such as rotenone. On a mechanistic level, we show that probenecid is able to lower intracellular ATP concentrations and that its toxic action on neuronal cells can be reversed by extracellular ATP. Probenecid can potentiate the effect of mitochondrial toxins due to its impact on ATP metabolism and could therefore be useful to model atypical parkinsonian syndromes.  +

Mitochondrial involvement plays an important role in neurodegenerative diseases. At least one-third of adult carriers of a ''FMR1'' premutation (55-200 CGG repeats) are at risk of presenting an adult-onset neurodegenerative disorder known as fragile X-associated tremor/ataxia syndrome (FXTAS). In an attempt to provide new insights into the mechanisms involved in the pathogenesis of FXTAS, we characterized mitochondrial function and dynamics by the assessment of oxidative respiratory chain function, mitochondrial content, oxidative stress levels, and mitochondrial network complexity. Regarding mitochondrial function, we found that mitochondrial respiratory capacity is compromised in skin fibroblasts whereas in blood, no differences were observed between the FXTAS and control groups. Furthermore, fibroblasts from FXTAS patients presented altered mitochondrial architecture, with more circular and less interconnected mitochondria being observed. Mitochondrial function and dynamics deregulation and characteristic of neurological disorders are present in FXTAS patients. These features might be limiting temporal and spatial bioenergetics cells supply and thus contributing to disease pathogenesis.  +

The present study evaluated the ''in vivo'' antitumor effects and toxicity of a new Ru(II) compound, cis-(Ru[phen]2[ImH]2)²⁺ (also called RuphenImH [RuC]), against Walker-256 carcinosarcoma in rats. After subcutaneous inoculation of Walker-256 cells in the right pelvic limb, male Wistar rats received 5 or 10mgkg^-1 RuC orally or intraperitoneally (i.p.) every 3 days for 13 days. A positive control group (2mgkg^-1 cisplatin) and negative control group (vehicle) were also used. Tumor progression was checked daily. After treatment, tumor weight, plasma biochemistry, hematology, oxidative stress, histology, and tumor cell respiration were evaluated. RuC was effective against tumors when administered i.p. but not orally. The highest i.p. dose of RuC (10mgkg^-1) significantly reduced tumor volume and weight, induced oxidative stress in tumor tissue, reduced the respiration of tumor cells, and induced necrosis but did not induce apoptosis in the tumor. No clinical signs of toxicity or death were observed in tumor-bearing or healthy rats that were treated with RuC. These results suggest that RuC has antitumor activity through the modulation of oxidative stress and impairment of oxidative phosphorylation, thus promoting Walker-256 cell death without causing systemic toxicity. These effects make RuC a promising anticancer drug for clinical evaluation. Copyright © 2017 Elsevier Inc. All rights reserved.  +

[[Image:MITOEAGLE-logo.jpg|left|100px|link=http://www.mitoglobal.org/index.php/MITOEAGLE|COST Action MitoEAGLE]] Bladder cancer (BC) has a high incidence and recurrence rate. In addition, patients have a poor survival expectancy. Multiple signaling pathways that interact with mitochondria are involved in events related to tumor aggressiveness and growth. Thus, molecular classification and characterization of the tumor is pivotal to predict clinical outcomes, responses to chemotherapy and develop novel treatments. There are several targets towards personalized medicine, including mitochondrial DNA, mitochondrial metabolic enzymes and cellular signaling proteins. Among those, the mammalian target of rapamycin (mTOR) and NAD-dependent deacetylase sirtuin-1 (SIRT1) are known to independently mediate some cancer related features and mitochondria functioning. Herein we aimed to characterize how the activation or inhibition of SIRT1 and/or mTOR modulate the metabolic and bioenergetics profiles of highly proliferative and invasive stage IV BC cells. For that purpose, TCCSUP cells (BC stage IV) were cultured during 24 h in a normal media or supplemented with EX527 (SIRT1 inhibitor); YK-3-237 (SIRT1 activator) and Rapamycin (mTOR inhibitor), as well as in a combined treatment of EX527+Rapamycin. In addition to cytotoxicity and migration tests, we determined the metabolic profile (metabolic fluxes, 1H-NMR), expression of membrane transporters (GLUT3 and MCT1/MCT4, qPCR), mitochondrial potential (JC-1 fluorescence), intact cell respirometry (Clark-type electrode) and mitochondrial copy number (qPCR) of the cells from each experimental group. Our results show that mTOR inhibition alone or in combination with SIRT1 activation decreased cell density in BC cells. In addition, mitochondrial potential of BC cells was repressed after exposure to the combined treatment of mTOR inhibition with SIRT1 activation/inhibition. In parallel with this, BC cells presented mitochondrial proton leak stimulation, with increased acetate consumption and decreased lactate production after the combined treatment with SIRT1/mTOR inhibitors. Interestingly, inhibition of mTOR alone upregulated the levels of transporters such as GLUT3 and MCT4, but there was no direct action on the levels of metabolites transported by these transporters. On the other hand, activation of SIRT1 downregulated the levels of MCT1 but again, it did not affect lactate levels in the extracellular medium. Overall, our results show that the combined inhibition of mTOR and SIRT1 in highly proliferative and invasive BC cells affects mitochondria physiology, which may elicit positive effects on the treatment of bladder cancer. Nevertheless, although our data shows promising results in the response of highly proliferative and invasive BC cells to the combined treatment with combined mTOR and SIRT1 inhibitors, this is a first assessment of the metabolic and bioenergetics profile of these cells. Further studies will be needed to unveil the molecular mechanisms by which mitochondria mediates the positive response of highly proliferative and invasive BC cells to the combined inhibition of mTOR and SIRT1.  

Malnutrition in the early stages of life may lead to changes in the glycemic metabolism during adulthood, such as pancreatic beta cells dysfunction and failure. Therefore, this study aimed to evaluate the effects of an ''in vitro'' amino acid restriction model on the function and viability of pancreatic beta cells. Insulin-producing cells (INS-1E) were maintained in control or amino acid restricted culture medium containing 1 × or 0.25 × of amino acids, respectively, for 48 h. Amino acid restricted group showed lower insulin secretion and insulin gene expression, reduced mitochondrial oxygen consumption rate and reactive oxygen species production. Besides, amino acid restricted group also showed higher levels of endoplasmic reticulum stress and apoptosis markers and enhanced Akt phosphorylation. However, even with higher levels of apoptosis markers, amino acid restricted group did not show higher levels of cell death unless the PI3K/Akt pathway was inhibited. Amino acid restricted beta cell viability seems to be dependent on the PI3K/Akt pathway.  +

At the request of the author, this abstract is not made available online.  +

Uncoupling proteins (UCPs) play a critical role in the control of the mitochondrial membrane potential (ΔΨm) due to their ability to dissipate the proton gradient, which results in the uncoupling of mitochondrial respiration from ATP production. Most reactive oxygen species generation in mitochondria occurs in complex III, due to an increase of semiquinone (Q-) half-life. When active, UCPs can account as a potential antioxidant system by decreasing ΔΨm and increasing mitochondrial respiration, thus reducing Q- life time. The hematophagous insect Rhodnius prolixus, a vector of Chagas disease, is exposed to a huge increase in oxidative stress after a blood meal because of the hydrolysis of hemoglobin and the release of the cytotoxic heme molecule. Although some protective mechanisms were already described for this insect and other hematophagous arthropods, the putative role of UCP proteins as antioxidants in this context has not been explored. In this report, two genes encoding UCP proteins (RpUcp4 and RpUcp5) were identified in the R. prolixus genome. RpUcp4 is the predominant transcript in most analyzed organs, and both mRNA and protein expression are upregulated (13- and 3-fold increase, respectively) in enterocytes the first day after the blood feeding. The increase in UCP4 expression is coincident with the decrease in hydrogen peroxide (H2O2) generation by midgut cells. Furthermore, in mitochondria isolated from enterocytes, the modulation of UCP activity by palmitic acid and GDP resulted in altered ΔΨm, as well as modulation of H2O2 generation rates. These results indicate that R. prolixus UCP4 may function in an antioxidation mechanism to protect the midgut cells against oxidative damage caused by blood digestion.  +

The malfunction of the finely tuned homeostatic systems that maintain oxidative balance is part of the pathology of almost every known human disease. There are scores of individual components and pathways which maintain oxidative balance. One or more of these maybe altered in disease, though it is difficult to determine what the triggering pathway or analyte is. In light of this, biomarkers are useful tools to evaluate oxidative imbalance or indicate the degree of oxidative stress. When selecting which biomarkers for oxidative stress, there are three categories of biomarkers to choose from. These depend on the target of oxidation and are isoprostanes, oxysterols, and hydroxyoctadecadienoic acid. Biomarkers of nucleic acid oxidation include nucleotides, single- and double-stranded breaks in DNA, and RNA oxidative products. Oxidative damage to proteins can be measured via protein carbonyls, glutathione levels, glycosylated hemoglobin, and erythrocyte oxidation from fluorescent heme degradation products. In isolation, each of these will give specific information on the target of oxidation, as well as providing tentative information regarding affected pathways. Here, we describe in detail the selective markers, protein carbonyls, oxysterols, isoprostanes, heme degradation products, HbA1C, and many more. All the above biomarkers are discussed in this review. As with ideal biomarkers, these have a mixed utility and can be measured in different tissues and compartments. In blood, each will provide a certain amount of information, which will vary between giving a systemic scope of oxidative stress (e.g., erythrocyte oxidation) to evaluating oxidative stress in specific diseases (e.g., glycosylated hemoglobin and diabetes). Ideally, it is better to select multiple biomarkers based on an in-depth knowledge of the condition at hand.  +

Medium-chain acyl-CoA dehydrogenase (MCAD) deficiency is biochemically characterized by tissue accumulation of octanoic (OA), decanoic (DA) and cis-4-decenoic (cDA) acids, as well as by their carnitine by-products. Untreated patients present episodic encephalopathic crises and biochemical liver alterations, whose pathophysiology is poorly known. We investigated the effects of OA, DA, cDA, octanoylcarnitine (OC) and decanoylcarnitine (DC) on critical mitochondrial functions in rat brain and liver. DA and cDA increased resting respiration and diminished ADP- and CCCP-stimulated respiration and complexes II-III and IV activities in both tissues. The data indicate that these compounds behave as uncouplers and metabolic inhibitors of oxidative phosphorylation. Noteworthy, metabolic inhibition was more evident in brain as compared to liver. DA and cDA also markedly decreased mitochondrial membrane potential, NAD(P)H content and Ca²⁺ retention capacity in Ca²⁺-loaded brain and liver mitochondria. The reduction of Ca²⁺ retention capacity was more pronounced in liver and totally prevented by cyclosporine A and ADP, as well as by ruthenium red, demonstrating the involvement of mitochondrial permeability transition (mPT) and Ca²⁺. Furthermore, cDA induced lipid peroxidation in brain and liver mitochondria and increased hydrogen peroxide formation in brain, suggesting the participation of oxidative damage in cDA-induced alterations. Interestingly, OA, OC and DC did not alter the evaluated parameters, implying lower toxicity for these compounds. Our results suggest that DA and cDA, in contrast to OA and medium-chain acylcarnitines, disturb important mitochondrial functions in brain and liver by multiple mechanisms that are possibly involved in the neuropathology and liver alterations observed in MCAD deficiency. Copyright © 2016 Elsevier B.V. All rights reserved.  +

Accumulation of 2-methylcitric acid (2MCA) is observed in methylmalonic and propionic acidemias, which are clinically characterized by severe neurological symptoms. The exact pathogenetic mechanisms of brain abnormalities in these diseases are poorly established and very little has been reported on the role of 2MCA. In the present work we found that 2MCA markedly inhibited ADP-stimulated and uncoupled respiration in mitochondria supported by glutamate, with a less significant inhibition in pyruvate plus malate-respiring mitochondria. However, no alterations occurred when α-ketoglutarate or succinate was used as respiratory substrates, suggesting a defect on glutamate oxidative metabolism. It was also observed that 2MCA decreased ATP formation in glutamate plus malate or pyruvate plus malate-supported mitochondria. Furthermore, 2MCA inhibited glutamate dehydrogenase (GDH) activity at concentrations as low as 0.5 mM. Kinetic studies revealed that this inhibitory effect was competitive in relation to glutamate. In contrast, assays of osmotic swelling in non-respiring mitochondria suggested that 2MCA did not significantly impair mitochondrial glutamate transport. Finally, 2MCA provoked a significant decrease of mitochondrial membrane potential and induced swelling in Ca²⁺ -loaded mitochondria supported by different substrates. These effects were totally prevented by cyclosporine A plus ADP or ruthenium red, indicating induction of mitochondrial permeability transition (PT). Taken together, our data strongly indicate that 2MCA behaves as a potent inhibitor of glutamate oxidation by inhibiting GDH activity and as a PT inducer, disturbing mitochondrial energy homeostasis. We presume that 2MCA-induced mitochondrial deleterious effects may contribute to the pathogenesis of brain damage in patients affected by methylmalonic and propionic acidemias. This article is protected by copyright. All rights reserved.  +

Make science more reliable by placing the burden of replicability on the community, not on individual laboratories.  +

Over 4 million individuals in the United States, and over 140 million individuals worldwide, are exposed daily to arsenic-contaminated drinking water. Human exposures can range from below the current limit of 10μg/L to over 1mg/L, with 100μg/L promoting disease in a large portion of those exposed. Although increased attention has recently been paid to myopathy following arsenic exposure, the pathogenic mechanisms underlying clinical symptoms remain poorly understood. This study tested the hypothesis that arsenic induces lasting muscle mitochondrial dysfunction and impairs metabolism. Compared to nonexposed controls, mice exposed to drinking water containing 100μg/L arsenite for 5 weeks demonstrated impaired muscle function, mitochondrial myopathy, and altered oxygen consumption that were concomitant with increased mitochondrial fusion gene transcription. There were no differences in the levels of inorganic arsenic or its monomethyl and dimethyl metabolites between controls and exposed muscles, confirming that arsenic does not accumulate in muscle. Nevertheless, muscle progenitor cells isolated from exposed mice recapitulated the aberrant myofiber phenotype and were more resistant to oxidative stress, generated more reactive oxygen species, and displayed autophagic mitochondrial morphology, compared to cells isolated from nonexposed mice. These pathological changes from a possible maladaptive oxidative stress response provide insight into declines in muscle functioning caused by exposure to this common environmental contaminant.  +

[[Image:MITOEAGLE-logo.jpg|left|100px|link=http://www.mitoglobal.org/index.php/MITOEAGLE|COST Action MitoEAGLE]] Mitochondrial alterations are evident in various neurological diseases; and most notably, in the earliest presymptomatic stages of Alzheimers Disease (AD) pathology[1]. As a result, brain bioenergetics have emerged as an important topic of research. AD is associated with changes in brain pathology that manifest in specific brain regions, such as the frontal cortex and hippocampus. Therefore, our goal was to selectively examine the bioenergetic profiles of brain mitochondria isolated from distinct regions relevant to AD. Our approach utilized cynomolgus macaques as they have been demostrated to be reliable models for evaluating various age related diseases and conditions[2]. In addition, the use of non-human primates provides sufficient tissue for adequate mitochondrial yield from multiple brain regions as shown in '''Figure 1'''. We analyzed isolated mitochondria from prefrontal cortex, entorhinal cortex, and cerebellum from the same animal to determine how bioenergetic profiles may differ between these areas. Prefrontal cortex and entorhinal cortex were selected due to their relevance in AD pathology, while the cerebellar region was selected because it may serve as a useful control region in studies of AD pathology. Mitochondria were isolated from brain tissue using a manual glass-on-glass cell homogenizer and series of centrifugation steps. We utilized two SUIT protocols to examine respiration in high-resolution: RP2 and a previously published protocol by Lanza and Nair[3]. RP2 was selected because it is a standard reference protocol; thus, the methods have been well vetted and the results are easily interpreted. We were also interested in RP2 because it includes titrations to evaluate fatty acid oxidation. The protocol published by Lanza and Nair was applied because it offers an alternative approach that has been adopted by other research groups. By using two protocols we can compare to tease out additional information that one protocol alone may miss. Traces from the two protocols can be observed in '''Figure 2'''.  

Caloric restriction (CR) protects against many cerebral pathological conditions that are associated with excitotoxic damage and calcium overload, although the mechanisms are still poorly understood. Here we show that CR strongly protects against excitotoxic insults ''in vitro'' and ''in vivo'' in a manner associated with significant changes in mitochondrial function. CR increases electron transport chain activity, enhances antioxidant defenses, and favors mitochondrial calcium retention capacity in the brain. These changes are accompanied by a decrease in cyclophilin D activity and acetylation and an increase in Sirt3 expression. This suggests that Sirt3-mediated deacetylation and inhibition of cyclophilin D in CR promote the inhibition of mitochondrial permeability transition, resulting in enhanced mitochondrial calcium retention. Altogether, our results indicate that enhanced mitochondrial calcium retention capacity underlies the beneficial effects of CR against excitotoxic conditions. This protection may explain the many beneficial effects of CR in the aging brain. © 2016 The Authors. Aging Cell published by the Anatomical Society and John Wiley & Sons Ltd.  +

We introduce a general test of the bioenergetic importance of mtDNA (mitochondrial DNA) variants: modular kinetic analysis of oxidative phosphorylation in mitochondria from cybrid cells with constant nuclear DNA but different mtDNA. We have applied this test to the hypothesis [Ruiz-Pesini, Mishmar, Brandon, Procaccio and Wallace (2004) Science 303, 223-226] that particular mtDNA haplogroups (specific combinations of polymorphisms) that cause lowered coupling efficiency, leading to generation of less ATP and more heat, were positively selected during radiations of modern humans into colder climates. Contrary to the predictions of this hypothesis, mitochondria from Arctic haplogroups had similar or even greater coupling efficiency than mitochondria from tropical haplogroups.  +

Tumour cells are characterized by accelerated growth usually accompanied by up-regulated pathways that ultimately increase the rate of ATP production. These cells can suffer metabolic reprogramming, resulting in distinct bioenergetic phenotypes, generally enhancing glycolysis channelled to lactate production [1]. It has been highlighted that maintenance of energy homeostasis (both oxidative and glycolytic metabolism) is essential for tumour development control [2]. In this context we have investigated whether sodium butyrate (NaB), a histone deacetylase inhibitor, alters the energy metabolism in lung cancer cells (H460) and if these effects are related to differentiation, growth arrest and apoptosis observed in these cells exposed to 10mM NaB during 24 hours. We have shown that in this experimental condition, cells display reduced glycolytic flux indicated by lactate production. Results with high-resolution respirometry show increased oxidative metabolism leading to increased rates of oxygen consumption coupled to ATP synthesis. Mitochondria morphology, characterized by electron microscopy, showed increased size in the treated cells. These results can be associated to mitochondrial fusion because we have detected an increase in mitofusin mRNA. These alterations on the energetic metabolism after treatment with NaB suggest that there is an increase in mitochondrial function and enhanced oxidative metabolism. 1. Kroemer G, Pouyssegur J (2008) Tumor cell metabolism: cancer's Achilles' heel. Cancer Cell 13: 472-482. 2. Xu WS, Parmigiani RB, Marks PA (2007) Histone deacetylase inhibitors: molecular mechanisms of action. Oncogene 26: 5541-5552.  +