Mitochondrial H2O2 Emission Research Articles

Interactions of binary mixtures of metals on rainbow trout (Oncorhynchus mykiss) heart mitochondrial H2O2 homeodynamics

For continuous pumping of blood, the heart needs a constant supply of energy (ATP) that is primarily met via oxidative phosphorylation in the mitochondria of cardiomyocytes. However, sustained high rates of electron transport for energy conversion redox reactions predisposes the heart to the production of reactive oxygen species (ROS) and oxidative stress. Mitochondrial ROS are fundamental drivers of responses to environmental stressors including metals but knowledge of how combinations of metals alter mitochondrial ROS homeodynamics remains sparse. We explored the effects and interactions of binary mixtures of copper (Cu), cadmium (Cd), and zinc (Zn), metals that are common contaminants of aquatic systems, on ROS (hydrogen peroxide, H2O2) homeodynamics in rainbow trout (Oncorhynchus mykiss) heart mitochondria. Isolated mitochondria were energized with glutamate-malate or succinate and exposed to a range of concentrations of the metals singly and in equimolar binary concentrations. Speciation analysis revealed that Cu was highly complexed by glutamate or Tris resulting in Cu2+ concentrations in the picomolar to nanomolar range. The concentration of Cd2+ was 7.2–7.5 % of the total while Zn2+ was 15 % and 21 % of the total during glutamate-malate and succinate oxidation, respectively. The concentration-effect relationships for Cu and Cd on mitochondrial H2O2 emission depended on the substrate while those for Zn were similar during glutamate-malate and succinate oxidation. Cu + Zn and Cu + Cd mixtures exhibited antagonistic interactions wherein Cu reduced the effects of both Cd and Zn, suggesting that Cu can mitigate oxidative distress caused by Cd or Zn. Binary combinations of the metals acted additively to reduce the rate constant and increase the half-life of H2O2 consumption while concomitantly suppressing thioredoxin reductase and stimulating glutathione peroxidase activities. Collectively, our study indicates that binary mixtures of Cu, Zn, and Cd act additively or antagonistically to modulate H2O2 homeodynamics in heart mitochondria.

Altered Hepatic Mitochondrial Bioenergetics and Oxidant Emission with Ischemia and Reperfusion

Rationale: Ischemia-reperfusion injury (IRI) is inevitable in liver transplantation (LT) which can be mitigated by normothermic machine perfusion (NMP) before LT. The current NMP liver viability criteria for LT mainly rely on bile production and perfusate lactate levels, factors that can also be affected by external variables such as NMP conditions and perfusate additives. Incorporating mitochondrial bioenergetic data could improve the predictive value of current NMP viability criteria for LT. Thus, the goal of this study was to evaluate mitochondrial oxygen consumption rate (OCR), membrane potential (Δψ), and H2O2 oxidant emission in control livers and in livers with IRI and to explore underlying mechanisms responsible for any observed differences. Methods: Healthy control livers and livers exposed to 60 minutes warm ischemia time (WIT) through in situ clamping of the portal vein and hepatic artery followed by 60 minutes reperfusion (IRI) were harvested from adult male Sprague-Dawley rats. Mitochondria from control and IRI livers were isolated using established protocols and assessed for their bioenergetics responses. Three different substrate combinations, namely, pyruvate+malate (PM), glutamate+malate (GM), and succinate were used, followed by addition(s) of ADP and the uncoupler FCCP. Two different ADP addition protocols were designed to determine how different substrates influence mitochondrial OCR, Δψ, and H2O2 emission during oxidative phosphorylation (OxPhos) between control and IRI conditions. In one protocol, a single saturated dose of ADP addition, and in the other, sequentially increasing doses of ADP additions were made following substrate addition. The OCR and Δψ were measured simultaneously using a dual chamber Oroboros Oxygraph-2k Instrument coupled to a fluorometer using the TMRM dye. The H2O2 emission was measured spectrofluorometrically using the amplex red and horseradish peroxidase assay. Results: The measured data show that the kinetics and effciency of OxPhos defining mitochondrial OCR and Δψ responses in the liver are negatively affected by IRI, characterized by enhanced H2O2 emission, in a substrate-dependent manner. Interestingly, the respiratory rates are higher when GM and succinate are utilized as substrates, whereas the use of PM shows comparatively lower respiration in both conditions. Control mitochondria exhibited higher respiratory rates than IRI mitochondria irrespective of the substrate utilized. The ADP-induced state 3 OCR in IRI mitochondria was 50% lower than that in control mitochondria resulting in doubling the duration of state 3 OCR. Similar differences were observed in Δψ for both ADP addition protocols. Compromised mitochondrial bioenergetics during IRI was observed using both single and sequentially increasing doses of ADP and was concomitant with a higher rate of H2O2 emission. Conclusion: This study provided novel quantitative data demonstrating the substrate specific changes in mitochondrial bioenergetics in hepatic IRI, which can be used to improve the NMP viability criteria for LT. The obtained bioenergetics and H2O2 emission data indicate that, during IRI, mitochondrial function is highly affected which may critically impact energy dependent metabolism and lactate/pyruvate ratio. NIH R01-HL151587. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Impact of exercise training on endothelial metabolism and skeletal muscle angiogenic potential in type 2 diabetes

Type 2 diabetes (T2D) is associated with vascular endothelial dysfunction and microvascular rarefaction in skeletal muscle tissue (1). Although endothelial dysfunction in metabolic disease is proposed to be associated with altered endothelial cell metabolism, there is to date a paucity of human data to support this notion. The aim of this study was to investigate the metabolism in microvascular endothelial cells derived from skeletal muscle biopsies. Moreover, as exercise training is known to reverse endothelial dysfunction and promote angiogenesis, the effect of a period of exercise training was assessed. Microvascular endothelial cells were isolated from m. vastus lateralis biopsies taken from obese individuals with (n = 7) and without (n = 8) T2D before and after 12 weeks of aerobic exercise training. Mitochondrial respiration, hydrogen peroxide (H2O2) emission, and nitric oxide (NO) formation were determined in the cells by the Oroboros Oxygraph-2K. In addition, angiogenic-, metabolic- and antioxidant enzymes and proteins, cell proliferation, and skeletal muscle capillarization were determined. At baseline, there was no difference between endothelial cells from obese control participants and T2D obese participants for any of the parameters measured: glycolytic capacity, as evidenced by a similar lactate production and PFK-1 protein content, respiratory capacity, H2O2 emission, NO emission, endothelial NO synthase protein (eNOS) content. The training period led to an overall increase in the respiratory capacity in endothelial cells from both groups (main effect, P = 0.021) whereas mitochondrial H2O2 emission remained unaltered. There was no change in glycolytic capacity, superoxide dismutase 2 or eNOS protein contents, or NO emission. Training did not influence the capillary-to-muscle fiber ratio in either group. The results of this study show that aerobic exercise training of obese control and obese diabetic subjects leads to an increase in the respiratory capacity of muscle microvascular endothelial cells. The data also indicate that there are no differences in endothelial metabolism and NO production between obese control and obese diabetic individuals. However, as the study is ongoing and only half of the subjects have been included at this time, power is limited and results may differ upon completion. Data from all subjects will be presented at the conference. Funding: The study is funded by Novo Nordisk A/S. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

MFN2 overexpression in skeletal muscles of young and old mice causes a mild hypertrophy without altering mitochondrial respiration and H2O2 emission.

Sarcopenia, the aging-related loss of muscle mass and function, is a debilitating process negatively impacting the quality of life of affected individuals. Although the mechanisms underlying sarcopenia are incompletely understood, impairments in mitochondrial dynamics, including mitochondrial fusion, have been proposed as a contributing factor. However, the potential of upregulating mitochondrial fusion proteins to alleviate the effects of aging on skeletal muscles remains unexplored. We therefore hypothesized that overexpressing Mitofusin 2 (MFN2) in skeletal muscle invivo would mitigate the effects of aging on muscle mass and improve mitochondrial function. MFN2 was overexpressed in young (7 mo) and old (24 mo) male mice for 4 months through intramuscular injections of an adeno-associated viruses. The impacts of MFN2 overexpression on muscle mass and fiber size (histology), mitochondrial respiration, and H2O2 emission (Oroboros fluororespirometry), and various signaling pathways (qPCR and western blotting) were investigated. MFN2 overexpression increased muscle mass and fiber size in both young and old mice. No sign of fibrosis, necrosis, or inflammation was found upon MFN2 overexpression, indicating that the hypertrophy triggered by MFN2 overexpression was not pathological. MFN2 overexpression even reduced the proportion of fibers with central nuclei in old muscles. Importantly, MFN2 overexpression had no impact on muscle mitochondrial respiration and H2O2 emission in both young and old mice. MFN2 overexpression attenuated the increase in markers of impaired autophagy in old muscles. MFN2 overexpression may be a viable approach to mitigate aging-related muscle atrophy and may have applications for other muscle disorders.

Chronic kidney disease and left ventricular diastolic dysfunction (CKD-LVDD) alter cardiac expression of mitochondria-related genes in swine

Cardiovascular disease and heart failure doubles in patients with chronic kidney disease (CKD), but the underlying mechanisms remain obscure. Mitochondria are central to maintaining cellular respiration and modulating cardiomyocyte function. We took advantage of our novel swine model of CKD and left ventricular diastolic dysfunction (CKD-LVDD) to investigate the expression of mitochondria-related genes and potential mechanisms regulating their expression. CKD-LVDD and normal control pigs (n=6/group, 3 males/3 females) were studied for 14 weeks. Renal and cardiac hemodynamics were quantified by multidetector-CT, echocardiography, and pressure-volume loop studies, respectively. Mitochondrial morphology (electron microscopy) and function (Oroboros) were assessed ex vivo. In randomly selected pigs (n=3/group), cardiac mRNA-, MeDIP-, and miRNA-sequencing (seq) were performed to identify mitochondria-related genes and study their pre- and post -transcriptional regulation. CKD-LVDD exhibited cardiac mitochondrial structural abnormalities and elevated mitochondrial H2O2 emission but preserved mitochondrial function. Cardiac mRNA-seq identified 862 mitochondria-related genes, of which 69 were upregulated and 33 downregulated (fold-change ≥2, false discovery rate≤0.05). Functional analysis showed that upregulated genes were primarily implicated in processes associated with oxidative stress, whereas those downregulated mainly participated in respiration and ATP synthesis. Integrated mRNA/miRNA/MeDIP-seq analysis showed that upregulated genes were modulated predominantly by miRNAs, whereas those downregulated were by miRNA and epigenetic mechanisms. CKD-LVDD alters cardiac expression of mitochondria-related genes, associated with mitochondrial structural damage but preserved respiratory function, possibly reflecting intrinsic compensatory mechanisms. Our findings may guide the development of early interventions at stages of cardiac dysfunction in which mitochondrial injury could be prevented, and the development of LVDD ameliorated.

Effect of skeletal muscle mitochondrial phenotype on H2O2 emission

Reactive oxygen species (ROS) are a key output of the skeletal muscle mitochondrial information processing system both at rest and during exercise. In skeletal muscle, mitochondrial ROS release depends on multiple factors; however, fiber-type specific differences remain ambiguous in part owing to the use of mitochondria from mammalian muscle that consist of mixed fibers. To elucidate fiber-type specific differences, we used mitochondria isolated from rainbow trout (Oncorhynchus mykiss) red and white skeletal muscles that consist of spatially distinct essentially pure red and white fibers. We first characterized the assay conditions for measuring ROS production (as H2O2) in isolated fish red and white skeletal muscle mitochondria (RMM and WMM) and thereafter compared the rates of emission during oxidation of different substrates and the responses to mitochondrial electron transport system (ETS) pharmacological modulators. Our results showed that H2O2 emission rates by RMM and WMM can be quantified using the same protein concentration and composition of the Amplex UltraRed-horseradish peroxidase (AUR-HRP) detection system. For both RMM and WMM, protein normalized H2O2 emission rates were highest at the lowest protein concentration tested and decreased exponentially thereafter. However, the absolute values of H2O2 emission rates depended on the calibration curves used to convert fluorescent signals to H2O2 while the trends depended on the normalization strategy. We found substantial qualitative and quantitative differences between RMM and WMM in the H2O2 emission rates depending on the substrates being oxidized and their concentrations. Similarly, pharmacological modulators of the ETS altered the magnitudes and trends of the H2O2 emission differently in RMM and WMM. While comparable concentrations of substrates elicited maximal albeit quantitively different emission rates in RMM and WMM, different concentrations of pharmacological ETS modulators may be required for maximal H2O2 emission rates depending on muscle fiber-type. Taken together, our study suggests that biochemical differences exist in RMM compared with WMM that alter substrate oxidation and responses to ETS modulators resulting in fiber-type specific mitochondrial H2O2 emission rates.

Exhaustive exercise alters native and site-specific H2O2 emission in red and white skeletal muscle mitochondria

Mitochondrial reactive oxygen species (ROS) homeostasis is intricately linked to energy conversion reactions and entails regulation of the mechanisms of ROS production and removal. However, there is limited understanding of how energy demand modulates ROS balance. Skeletal muscle experiences a wide range of energy requirements depending on the intensity and duration of exercise and therefore is an excellent model to probe the effect of altered energy demand on mitochondrial ROS production. Because in most fish skeletal muscle exists essentially as pure spatially distinct slow-twitch red oxidative and fast-twitch white glycolytic fibers, it provides a natural system for investigating how functional specialization affects ROS homeostasis. We tested the hypothesis that acute increase in energy demand imposed by exhaustive exercise will increase mitochondrial H2O2 emission to a greater extent in red muscle mitochondria (RMM) compared with white muscle mitochondria (WMM). We found that native H2O2 emission rates varied by up to 6-fold depending on the substrate being oxidized and muscle fiber type, with RMM emitting at higher rates with glutamate-malate and palmitoylcarnitine while WMM emitted at higher rates with succinate and glyceral-3-phosphate. Exhaustive exercise increased the native and site-specific H2O2 emission rates; however, the maximal emission rates depended on the substrate, fiber type and redox site. The H2O2 consumption capacity and activities of individual antioxidant enzymes including the glutathione- and thioredoxin-dependent peroxidases as well as catalase were higher in RMM compared with WMM indicating that the activity of antioxidant defense system does not explain the differences in H2O2 emission rates in RMM and WMM. Overall, our study suggests that substrate selection and oxidation may be the key factors determining the rates of ROS production in RMM and WMM following exhaustive exercise.

Muscle weakness precedes atrophy during cancer cachexia and is linked to muscle-specific mitochondrial stress.

Muscle weakness and wasting are defining features of cancer-induced cachexia. Mitochondrial stress occurs before atrophy in certain muscles, but the possibility of heterogeneous responses between muscles and across time remains unclear. Using mice inoculated with Colon-26 cancer, we demonstrate that specific force production was reduced in quadriceps and diaphragm at 2 weeks in the absence of atrophy. At this time, pyruvate-supported mitochondrial respiration was lower in quadriceps while mitochondrial H2O2 emission was elevated in diaphragm. By 4 weeks, atrophy occurred in both muscles, but specific force production increased to control levels in quadriceps such that reductions in absolute force were due entirely to atrophy. Specific force production remained reduced in diaphragm. Mitochondrial respiration increased and H2O2 emission was unchanged in both muscles versus control while mitochondrial creatine sensitivity was reduced in quadriceps. These findings indicate muscle weakness precedes atrophy and is linked to heterogeneous mitochondrial alterations that could involve adaptive responses to metabolic stress. Eventual muscle-specific restorations in specific force and bioenergetics highlight how the effects of cancer on one muscle do not predict the response in another muscle. Exploring heterogeneous responses of muscle to cancer may reveal new mechanisms underlying distinct sensitivities, or resistance, to cancer cachexia.

Short-term exposure to a clinical dose of metformin increases skeletal muscle mitochondrial H2O2 emission and production in healthy, older adults: A randomized controlled trial.

Metformin is the most commonly prescribed medication to treat diabetes. Emerging evidence suggests that metformin could have off target effects that might help promote healthy muscle aging, but these effects have not been thoroughly studied in glucose tolerant older individuals. The purpose of this study was to investigate the short-term effects of metformin consumption on skeletal muscle mitochondrial bioenergetics in healthy older adults. We obtained muscle biopsy samples from 16 healthy older adults previously naïve to metformin and treated with metformin (METF; 3F, 5M), or placebo (CON; 3F, 5M), for two weeks using a randomized and blinded study design. Samples were analyzed using high-resolution respirometry, immunofluorescence, and immunoblotting to assess muscle mitochondrial bioenergetics, satellite cell (SC) content, and associated protein markers. We found that metformin treatment did not alter maximal mitochondrial respiration rates in muscle compared to CON. In contrast, mitochondrial H2O2 emission and production were elevated in muscle samples from METF versus CON (METF emission: 2.59±0.72 SE Fold, P=0.04; METF production: 2.29±0.53 SE Fold, P=0.02). Furthermore, the change in H2O2 emission was positively correlated with the change in type 1 myofiber SC content and this was biased in METF participants (Pooled: R2=0.5816, P=0.0006; METF: R2=0.674, P=0.0125). These findings suggest that acute exposure to metformin does not impact mitochondrial respiration in aged, glucose-tolerant muscle, but rather, influences mitochondrial-free radical and SC dynamics. NCT03107884, clinicaltrials.gov.

Substrate‐Dependent Differential Regulation of Mitochondrial Bioenergetics and ROS emission in the Heart and Kidney Cortex and Outer Medulla

RationaleThe kinetics and efficiency of mitochondrial oxidative phosphorylation (OxPhos) is determined by the availability and utilization of particular respiratory substrates. Although the heart and kidney represent the two major energy consuming organs in the body, the substrate dependency of their mitochondrial OxPhos has not been characterized for these two organs within the same species and same individual animal.MethodThe effects of different substrate combinations on the kinetics and efficiency of OxPhos were characterized in mitochondria isolated from the heart, renal cortex, and renal outer medulla (OM) of adult Sprague‐Dawley rats. The substrate combinations included pyruvate+malate (PM), glutamate+malate (GM), palmitoyl‐carnitine+malate (PCM), alpha‐ketoglutarate+malate (AM), and succinate±rotenone (Suc±Rot). Mitochondrial bioenergetics (O2 consumption and membrane potential) and H2O2 emission were studied using two protocols: addition of a fixed [ADP] and sequential additions of incremental [ADP] in the presence of different substrates to determine how these substrates influence mitochondrial functional markers in each of these tissues.ResultsResults show that the kinetics and efficiency of mitochondrial OxPhos are highly dependent on the substrates used and this dependency is tissue‐specific. Heart mitochondria showed higher respiratory rates and OxPhos efficiencies for all substrates used in comparison to kidney mitochondria. Renal cortex mitochondrial respiratory rates were higher than OM mitochondria, but OM mitochondria OxPhos efficiencies were higher than cortex mitochondria. It was also found that heart mitochondria do not synthesize ATP efficiently from ADP with Suc in the absence of Rot (blocker of complex I). This may be due to (i) accumulation of oxaloacetate (OAA) and/or (ii) occurrence of reverse electron transfer (RET). In contrast, cortex and OM mitochondria achieved the same respiratory rates with Suc±Rot suggesting that efficient conversion of ADP to ATP by kidney mitochondria can occur in the presence of Suc. Similar differences were observed in mitochondrial membrane potential. However, differences in H2O2 emission in the presence of Suc±Rot were observed in heart mitochondria and to a lesser extent in OM mitochondria, but not in cortex mitochondria. The bioenergetics and H2O2 emission data observed with Suc±Rot indicate that OAA accumulation and RET play a more prominent regulatory role in heart mitochondria than in kidney mitochondria.ConclusionThis study provided novel quantitative data demonstrating that the choice of respiratory substrates affects mitochondrial bioenergetics and H2O2 emission in a tissue‐specific manner.

Factors affecting liver mitochondrial hydrogen peroxide emission.

Mitochondria are key cellular sources of reactive oxygen species (ROS) and contain at least 12 known sites on multiple enzymes that convert molecular oxygen to superoxide and hydrogen peroxide (H2O2). Quantitation of site-specific ROS emission is critical to understand the relative contribution of different sites and the pathophysiologic importance of mitochondrial ROS. However, factors that affect mitochondrial ROS emission are not well understood. We characterized and optimized conditions for maximal total and site-specific H2O2 emission during oxidation of standard substrates and probed the source of the high H2O2 emission in unenergized rainbow trout liver mitochondria. We found that mitochondrial H2O2 emission capacity depended on the substrate being oxidized, mitochondrial protein concentration, and composition of the ROS detection system. Contrary to our expectation, addition of exogenous superoxide dismutase reduced H2O2 emission. Titration of conventional mitochondrial electron transfer system (ETS) inhibitors over a range of conditions revealed that one size does not fit all; inhibitor concentrations evoking maximal responses varied with substrate and were moderated by the presence of other inhibitors. Moreover, the efficacy of suppressors of electron leak (S1QEL1.1 and S3QEL2) was low and depended on the substrate being oxidized. We found that H2O2 emission in unenergized rainbow trout liver mitochondria was suppressed by GKT136901 suggesting that it is associated with NADPH oxidase activity. We conclude that optimization of assay conditions is critical for quantitation of maximal H2O2 emission and would facilitate more valid comparisons of mitochondrial total and site-specific H2O2 emission capacities between studies, tissues, and species.

Copper modulates heart mitochondrial H2O2 emission differently during fatty acid and pyruvate oxidation

Although the preferred cardiac metabolic fuels are fatty acids, glucose metabolism also plays an important role. However, irrespective of substrate type, energy generation results in mitochondrial reactive oxygen species (ROS) formation. To determine if the preference of fat over carbohydrates predisposes cardiomyocytes to oxidant production, we measured total and site-specific H2O2 emission in heart mitochondria oxidizing palmitoylcarnitine or pyruvate during copper (Cu) exposure. H2O2 emission was higher during oxidation of palmitoylcarnitine compared with pyruvate. Moreover, the bulk of the H2O2 emitted during palmitoylcarnitine oxidation originated from the outer ubiquinone binding site of complex III (site IIIQo) and the flavin site of electron transfer flavoprotein (site EF). We found no evidence of ROS production from complex I ubiquinone-binding site (site IQ) by reverse electron transport during oxidation of palmitoylcarnitine. Pyruvate oxidation also drove H2O2 emission primarily from sites IIIQo; however, the flavin sites of pyruvate dehydrogenase (site PF) and complex II (site IIF) contributed substantially. The effect of Cu depended on substrate and redox site, with effects at sites OF and IIIQo being more pronounced in mitochondria oxidizing pyruvate compared with palmitoylcarnitine. Cu imposed a concentration-saturable effect at site PF but concentration-dependently stimulated H2O2 emission at site EF. The substrate-dependent differences in H2O2 emission and effects of Cu suggest that fuel type and points of entry of electrons into the mitochondrial electron transport system determine the mitochondrial ROS production rate. Importantly, knowledge of sites of mitochondrial ROS production is crucial to the understanding of cardiac dysfunction associated with impaired substrate metabolism.

Anoxia-reoxygenation modulates cadmium-induced liver mitochondrial reactive oxygen species emission during oxidation of glycerol 3-phosphate

Aquatic organisms are frequently exposed to multiple stressors including low dissolved oxygen (O2) and metals such as cadmium (Cd). Reduced O2 concentration and Cd exposure alter cellular function in part by impairing energy metabolism and dysregulating reactive oxygen species (ROS) homeostasis. However, little is known about the role of mitochondrial glycerol 3-phosphate dehydrogenase (mGPDH) in ROS homeostasis in fish and its response to environmental stress. In this study, mGPDH activity and the effects of anoxia-reoxygenation (A-RO) and Cd on ROS (as hydrogen peroxide, H2O2) emission in rainbow trout liver mitochondria during oxidation of glycerol 3-phosphate (G3P) were probed. Trout liver mitochondria exhibited low mGPDH activity that supported a low respiratory rate but substantial H2O2 emission rate. Cd evoked a low concentration stimulatory-high concentration inhibitory H2O2 emission pattern that was blunted by A-RO. At specific redox centers, Cd suppressed H2O2 emission from site IQ, but stimulated emission from sites IIIQo and GQ. In contrast, A-RO stimulated H2O2 emission from site IQ following 15 min exposure and augmented Cd-stimulated emission from site IIF after 30 min exposure but did not alter the rate of H2O2 emission from sites IIIQo and GQ. Additionally, Cd neither altered the activities of catalase, glutathione peroxidase, or thioredoxin reductase nor the concentrations of total glutathione, reduced glutathione, or oxidized glutathione. Overall, this study indicates that oxidation of G3P drives ROS production from mGPDH and complexes I, II and III, whereas Cd directly modulates redox sites but not antioxidant defense systems to alter mitochondrial H2O2 emission.

Fission accomplished: Uncovering the role of Drp1 in regulating mitochondrial dysfunction and age-related muscle atrophy.

Fission accomplished: Uncovering the role of Drp1 in regulating mitochondrial dysfunction and age-related muscle atrophy.

Sex and race contribute to variation in mitochondrial function and insulin sensitivity.

ObjectiveInsulin sensitivity is lower in African American (AA) versus Caucasian American (CA). We tested the hypothesis that lower insulin sensitivity in AA could be explained by mitochondrial respiratory rates, coupling efficiency, myofiber composition, or H2O2 emission. A secondary aim was to determine whether sex affected the results.MethodsAA and CA men and women, 19–45 years, BMI 17–43 kg m2, were assessed for insulin sensitivity (SIClamp) using a euglycemic clamp at 120 mU/m2/min, muscle mitochondrial function using high‐resolution respirometry, H2O2 emission using amplex red, and % myofiber composition.ResultsSIClamp was greater in CA (p < 0.01) and women (p < 0.01). Proportion of type I myofibers was lower in AA (p < 0.01). Mitochondrial respiratory rates, coupling efficiency, and H2O2 production did not differ with race. Mitochondrial function was positively associated with insulin sensitivity in women but not men. Statistical adjustment for mitochondrial function, H2O2 production, or fiber composition did not eliminate the race difference in SIClamp.ConclusionNeither mitochondrial respiratory rates, coupling efficiency, myofiber composition, nor mitochondrial reactive oxygen species production explained lower SIClamp in AA compared to CA. The source of lower insulin sensitivity in AA may be due to other aspects of skeletal muscle that have yet to be identified.

Acute erythropoietin injection increases muscle mitochondrial respiratory capacity in young men: a double-blinded randomized crossover trial.

The aim was to investigate if acute recombinant human erythropoietin (rHuEPO) injection had an effect on mitochondrial function and if exercise would have an additive effect. Furthermore, to investigate if in vitro incubation with rHuEPO had an effect on muscle mitochondrial respiratory capacity. Eight healthy young men were recruited for this double-blinded randomized placebo-controlled crossover study. rHuEPO (400 IU/kg body wt) or saline injection was given intravenously, before an acute bout of exercise. Resting metabolic rate and fat oxidation were measured. Biopsies were obtained at baseline, 120 min after injection, and right after the acute exercise bout. Mitochondrial function (mitochondrial respiration and H2O2 emission) was measured in permeabilized skeletal muscle using high-resolution respirometry and fluorometry. Specific gene expression and enzyme activity were measured. Skeletal muscle mitochondrial respiratory capacity was measured with and without incubation with rHuEPO. Fat oxidation at rest increased after rHuEPO injection, but no difference was found in fat oxidation during exercise. Mitochondrial respiratory capacity was increased after rHuEPO injection when pyruvate was in the assay, which was not the case when saline was injected. No changes were seen in H2O2 emission after rHuEPO injection or acute exercise. Incubation of skeletal muscle fibers in vitro with rHuEPO increased mitochondrial respiratory capacity. Acute rHuEPO injection increased mitochondrial respiratory capacity when pyruvate was used in the assay. No statistical difference was found in H2O2 emission capacity, although a numerical increase was seen after rHuEPO injection. In vitro incubation of the skeletal muscle sample with rHuEPO increases mitochondrial respiratory capacity.NEW & NOTEWORTHY The effect of an acute rHuEPO injection on skeletal muscle mitochondrial function was investigated in young healthy male subjects. rHuEPO has an acute effect on skeletal muscle mitochondrial respiratory capacity in humans, where an increased mitochondrial respiratory capacity was seen. This could be the first step leading to increased mitochondrial biogenesis.

Mitochondrial responses towards intermittent heat shocks in the eastern oyster, Crassostrea virginica.

Frequent heat waves caused by climate change can give rise to physiological stress in many animals, particularly in sessile ectotherms such as bivalves. Most studies characterizing thermal stress in bivalves focus on evaluating the responses to a single stress event. This does not accurately reflect the reality faced by bivalves, which are often subject to intermittent heat waves. Here, we investigated the effect of intermittent heat stress on mitochondrial functions of the eastern oyster, Crassostrea virginica, which play a key role in setting the thermal tolerance of ectotherms. Specifically, we measured changes in mitochondrial oxygen consumption and H2O2 emission rates before, during and after intermittent 7.5°C heat shocks in oysters acclimated to 15 and 22.5°C. Our results showed that oxygen consumption was impaired following the first heat shock at both acclimation temperatures. After the second heat shock, results for oysters acclimated to 15°C indicated a return to normal. However, oysters acclimated to 22.5°C struggled more with the compounding effects of intermittent heat shocks as denoted by an increased contribution of FAD-linked substrates to mitochondrial respiration as well as high levels of H2O2 emission rates. However, both acclimated populations showed signs of potential recovery 10days after the second heat shock, reflecting a surprising resilience to heat waves by C. virginica. Thus, this study highlights the important role of acclimation in the oyster's capacity to weather intermittent heat shock.

Nox4 Knockout Does Not Prevent Diaphragm Atrophy, Contractile Dysfunction, or Mitochondrial Maladaptation in the Early Phase Post-Myocardial Infarction in Mice.

Diaphragm dysfunction with increased reactive oxygen species (ROS) occurs within 72 hrs post-myocardial infarction (MI) in mice and may contribute to loss of inspiratory maximal pressure and endurance in patients. We used wild-type (WT) and whole-body Nox4 knockout (Nox4KO) mice to measure diaphragm bundle force in vitro with a force transducer, mitochondrial respiration in isolated fiber bundles with an O2 sensor, mitochondrial ROS by fluorescence, mRNA (RT-PCR) and protein (immunoblot), and fiber size by histology 72 hrs post-MI. MI decreased diaphragm fiber cross-sectional area (CSA) (~15%, p = 0.015) and maximal specific force (10%, p = 0.005), and increased actin carbonylation (5-10%, p = 0.007) in both WT and Nox4KO. Interestingly, MI did not affect diaphragm mRNA abundance of MAFbx/atrogin-1 and MuRF-1 but Nox4KO decreased it by 20-50% (p < 0.01). Regarding the mitochondria, MI and Nox4KO decreased the protein abundance of citrate synthase and subunits of electron transport system (ETS) complexes and increased mitochondrial O2 flux (JO2) and H2O2 emission (JH2O2) normalized to citrate synthase. Mitochondrial electron leak (JH2O2/JO2) in the presence of ADP was lower in Nox4KO and not changed by MI. Our study shows that the early phase post-MI causes diaphragm atrophy, contractile dysfunction, sarcomeric actin oxidation, and decreases citrate synthase and subunits of mitochondrial ETS complexes. These factors are potential causes of loss of inspiratory muscle strength and endurance in patients, which likely contribute to the pathophysiology in the early phase post-MI. Whole-body Nox4KO did not prevent the diaphragm abnormalities induced 72 hrs post-MI, suggesting that systemic pharmacological inhibition of Nox4 will not benefit patients in the early phase post-MI.

Critical Role for Hepatocyte-Specific eNOS in NAFLD and NASH.

Regulation of endothelial nitric oxide synthase (eNOS) in hepatocytes may be an important target in nonalcoholic fatty liver disease (NAFLD) development and progression to nonalcoholic steatohepatitis (NASH). In this study, we show genetic deletion and viral knockdown of hepatocyte-specific eNOS exacerbated hepatic steatosis and inflammation, decreased hepatic mitochondrial fatty acid oxidation and respiration, increased mitochondrial H2O2 emission, and impaired the hepatic mitophagic (BNIP3 and LC3II) response. Conversely, overexpressing eNOS in hepatocytes in vitro and in vivo increased hepatocyte mitochondrial respiration and attenuated Western diet-induced NASH. Moreover, patients with elevated NAFLD activity score (histology score of worsening steatosis, hepatocyte ballooning, and inflammation) exhibited reduced hepatic eNOS expression, which correlated with reduced hepatic mitochondrial fatty acid oxidation and lower hepatic protein expression of mitophagy protein BNIP3. The current study reveals an important molecular role for hepatocyte-specific eNOS as a key regulator of NAFLD/NASH susceptibility and mitochondrial quality control with direct clinical correlation to patients with NASH.

Investigating the Therapeutic Potential of Altering Drp1 Expression to Counter Sarcopenia

Rationale The aging-related loss of skeletal muscle mass and function, or sarcopenia, is a debilitating process dramatically impairing the quality of life of afflicted individuals. Although the mechanisms underlying sarcopenia are still only partly understood, impairments in mitochondrial dynamics, and notably in mitochondrial fission, have been proposed as an underlying mechanism. Importantly, conflicting data exist in the field and both excessive and insufficient mitochondrial fission were proposed to contribute to sarcopenia. Interestingly, promoting mitochondrial fission in midlife through Drp1 overexpression was recently shown to extend lifespan and attenuate several key hallmarks of muscle aging in flies. However, to date, whether modulating mitochondrial fission can impact the muscle aging process in mammals has never been investigated. Objective To define whether altering Drp1 expression in skeletal muscles of late middle-aged mice can impact the muscle aging process. Methods Drp1 expression was knocked down or overexpressed for 4 months in the gastrocnemius and tibialisanterior muscles of 18 months-old C57BL/6J mice using intramuscular injections of Adeno-Associated Viruses (AAVs). Results Drp1 knockdown in middle-aged mice resulted in severe muscle atrophy (-35 to 52%). Drp1 overexpression also resulted in muscle atrophy, although to a milder extend (-9%). Drp1 knockdown resulted in reduced mitochondrial respiration coupled with an increase in mitochondrial content. Drp1 overexpression did not impact maximal mitochondrial respiration but increased the content of proteins involved in the oxidative phosphorylation, indicating altered mitochondrial quality. Neither Drp1 overexpression nor Drp1 knockdown altered mitochondrial H2O2emission. Drp1 knockdown, but not Drp1 overexpression, resulted in an increase in markers of oxidative stress, muscle degeneration and impaired autophagy. Conclusions Taken altogether, our results indicate that both overexpressing and silencing Drp1 late in life negatively impact skeletal muscles and their mitochondria. These results highlight that Drp1 content must be remain within a fairly narrow physiological range to preserve muscle and mitochondrial integrity during aging. Our results finally emphasize that altering Drp1 expression is unlikely to be a viable target to counter sarcopenia.