Mitochondrial Preparations Research Articles

Leg cycling efficiency is unaltered in healthy aging regardless of sex or training status.

Muscular efficiency during exercise has been used to interrogate aspects of human muscle energetics, including mitochondrial coupling and biomechanical efficiencies. Typically, assessments of muscular efficiency have involved graded exercises. Results of previous studies have been interpreted to indicate a decline in exercise efficiency with aging owing to decreased mitochondrial function. However, discrepancies in variables such as exercise stage duration, cycling cadence, and treadmill walking mechanics may have affected interpretations of results. Furthermore, recent data from our lab examining the ATP to oxygen ratio (P:O) in mitochondrial preparations isolated from NIA mouse skeletal muscle showed no change with aging. Thus, we hypothesized that delta efficiency (Δ€) during steady-rate cycling exercise would not be altered in older healthy subjects compared with young counterparts regardless of biological sex or training status. Young (21-35 yr) and older (60-80 yr) men (n = 21) and women (n = 20) underwent continual, progressive leg cycle ergometer tests pedaling at 60 RPM for three stages (35, 60, 85 W) lasting 4 min. Δ€was calculated as: (Δ work accomplished/Δ energy expended). Overall, cycling efficiencies were not significantly different in older compared with young subjects. Similarly, trained subjects did not exhibit significantly different exercise efficiencies compared to untrained. Moreover, there were no differences between men and women. Hence, our results obtained on healthy young and older subjects are interpreted to mean that previous reports of decreased efficiency in older individuals were attributable to metabolic or biomechanical comorbidities, not aging per se.NEW & NOTEWORTHY Muscular power is reduced, but the efficiency of movement is unaltered in healthy aging.

Electron transfer pathways and coupling control in OXPHOS analysis of mouse and human mitochondrial preparations

Electron transfer pathways and coupling control in OXPHOS analysis of mouse and human mitochondrial preparations

Galactose-1-phosphate inhibits cytochrome c oxidase and causes mitochondrial dysfunction in classic galactosemia

Classic galactosemia is an inborn error of metabolism caused by mutations in the GALT gene resulting in the diminished activity of the galactose-1-phosphate uridyltransferase enzyme. This reduced GALT activity leads to the buildup of the toxic intermediate galactose-1-phosphate and a decrease in ATP levels upon exposure to galactose. In this work, we focused our attention on mitochondrial oxidative phosphorylation in the context of this metabolic disorder. We observed that galactose-1-phosphate accumulation reduced respiratory rates in vivo and changed mitochondrial function and morphology in yeast models of galactosemia. These alterations are harmful to yeast cells since the mitochondrial retrograde response is activated as part of the cellular adaptation to galactose toxicity. In addition, we found that galactose-1-phosphate directly impairs cytochrome c oxidase activity of mitochondrial preparations derived from yeast, rat liver, and human cell lines. These results highlight the evolutionary conservation of this biochemical effect. Finally, we discovered that two compounds - oleic acid and dihydrolipoic acid – that can improve the growth of cell models of mitochondrial diseases, were also able to improve galactose tolerance in this model of galactosemia. These results reveal a new molecular mechanism relevant to the pathophysiology of classic galactosemia - galactose-1-phosphate-dependent mitochondrial dysfunction - and suggest that therapies designed to treat mitochondrial diseases may be repurposed to treat galactosemia.

Inflammatory and metabolic responses in the aging rat brain

AbstractBackgroundThe brain is an energetically demanding organ that mostly relies on glucose oxidation to sustain its sophisticated networks. Transcriptomic studies suggest metabolic‐related genes are downregulated in the aging brain but inflammation‐related genes are highly upregulated. Astrocytes are key mediators of brain inflammation and metabolism. Yet, the relationship between inflammatory signals and energy substrates consumption in the aging brain remains unclear. To address this question, we investigated the response of the young and aged rat brain metabolism to a nonsteroidal anti‐inflammatory (NSAID) drug.MethodFive young adults (4 mo), and five aged (24 mo) male Wistar rats were scanned using positron emission microtomography with 18F‐fluorodeoxyglucose ([18F]FDG‐PET). Scans were done under basal conditions or after three‐day treatment with 5mg/kg ketoprofen (i.p.), an NSAID known to cross the blood‐brain barrier. Standard uptake values ratios (SUVr, pons as reference) were calculated for the main brain regions. Synaptosome and total mitochondria preparations from the cortex had their oxygen consumption rates measured in an Oroboros Instrument, using a SUIT protocol. Results were analyzed by t‐test, with statistical significance P < 0.05.ResultUnder basal conditions, glucose uptake showed no differences between young and aged rats. After ketoprofen treatment, clusters of glucose hypermetabolism appeared in the cortex and hippocampus of the adult but not the aged brain. Synaptosomal and mitochondrial preparations did not present differences in ATP‐linked, maximal, or leak respiration between groups under basal conditions. However, aged synaptosomes (t = 3.417, p = 0.0112) and total mitochondria (t = 3.131, p = 0.0166) presented higher respiratory coupling ratios.ConclusionWe previously showed that [18F]FDG‐PET signal highly depends on astrocyte function. The lack of response to ketoprofen in aged rats may be related to astrocyte dysfunction in aging. As a counter‐response to the aging process, the brain mitochondria are highly coupled, keeping the system as efficient as necessary. Our findings indicate that brain metabolism might not be coupled to inflammation in the aged rat brain. Still, we identified a remarkable plasticity of the mitochondria, which can sustain physiological responses despite the aging process.

A practical perspective on how to develop, implement, execute, and reproduce high-resolution respirometry experiments: The physiologist's guide to an Oroboros O2k.

The development of high-resolution respirometry (HRR) has greatly expanded the analytical scope to study mitochondrial respiratory control relative to specific tissue/cell types across various metabolic states. Specifically, the Oroboros Oxygraph 2000 (O2k) is a common tool for measuring rates of mitochondrial respiration and is the focus of this perspective. The O2k platform is amenable for answering numerous bioenergetic questions. However, inherent variability with HRR-derived data, both within and amongst users, can impede progress in bioenergetics research. Therefore, we advocate for several vital considerations when planning and conducting O2k experiments to ultimately enhance transparency and reproducibility across laboratories. In this perspective, we offer guidance for best practices of mitochondrial preparation, protocol selection, and measures to increase reproducibility. The goal of this perspective is to propagate the use of the O2k, enhance reliability and validity for both new and experienced O2k users, and provide a reference for peer reviewers.

N-Acetylglutamate and N-acetylmethionine compromise mitochondrial bioenergetics homeostasis and glutamate oxidation in brain of developing rats: Potential implications for the pathogenesis of ACY1 deficiency

Aminoacylase 1 (ACY1) deficiency is an inherited metabolic disorder biochemically characterized by high urinary concentrations of aliphatic N-acetylated amino acids and associated with a broad clinical spectrum with predominant neurological signs. Considering that the pathogenesis of ACY1 is practically unknown and the brain is highly dependent on energy production, the in vitro effects of N-acetylglutamate (NAG) and N-acetylmethionine (NAM), major metabolites accumulating in ACY1 deficiency, on the enzyme activities of the citric acid cycle (CAC), of the respiratory chain complexes and glutamate dehydrogenase (GDH), as well as on ATP synthesis were evaluated in brain mitochondrial preparations of developing rats. NAG mildly inhibited mitochondrial isocitrate dehydrogenase 2 (IDH2) activity, moderately inhibited the activities of isocitrate dehydrogenase 3 (IDH3) and complex II-III of the respiratory chain and markedly suppressed the activities of complex IV and GDH. Of note, the NAG-induced inhibitory effect on IDH3 was competitive, whereas that on GDH was mixed. On the other hand, NAM moderately inhibited the activity of respiratory complexes II-III and GDH activities and strongly decreased complex IV activity. Furthermore, NAM was unable to modify any of the CAC enzyme activities, indicating a selective effect of NAG toward IDH mitochondrial isoforms. In contrast, the activities of citrate synthase, α-ketoglutarate dehydrogenase, malate dehydrogenase, and of the respiratory chain complexes I and II were not changed by these N-acetylated amino acids. Finally, NAG and NAM strongly decreased mitochondrial ATP synthesis. Taken together, the data indicate that NAG and NAM impair mitochondrial brain energy homeostasis.

Disturbance of mitochondrial functions caused by N-acetylglutamate and N-acetylmethionine in brain of adolescent rats: Potential relevance in aminoacylase 1 deficiency

Aminoacylase 1 (ACY1) deficiency is a rare genetic disorder that affects the breakdown of short-chain aliphatic N-acetylated amino acids, leading to the accumulation of these amino acid derivatives in the urine of patients. Some of the affected individuals have presented with heterogeneous neurological symptoms such as psychomotor delay, seizures, and intellectual disability. Considering that the pathological mechanisms of brain damage in this disorder remain mostly unknown, here we investigated whether major metabolites accumulating in ACY1 deficiency, namely N-acetylglutamate (NAG) and N-acetylmethionine (NAM), could be toxic to the brain by examining their in vitro effects on important mitochondrial properties. We assessed the effects of NAG and NAM on membrane potential, swelling, reducing equivalents, and Ca2+ retention capacity in purified mitochondrial preparations obtained from the brain of adolescent rats. NAG and NAM decreased mitochondrial membrane potential, reducing equivalents, and calcium retention capacity, and induced swelling in Ca2+-loaded brain mitochondria supported by glutamate plus malate. Notably, these changes were completely prevented by the classical inhibitors of mitochondrial permeability transition (MPT) pore cyclosporin A plus ADP and by ruthenium red, implying the participation of MPT and Ca2+ in these effects. Our findings suggest that NAG- and NAM-induced disruption of mitochondrial functions involving MPT may represent relevant mechanisms of neuropathology in ACY1 deficiency.

Comparing whole body and red muscle mitochondrial respiration in an active teleost fish, brook trout (Salvelinus fontinalis)

Understanding how metabolic costs change in relation to increasing temperature under future climate changes is important to predict how ectotherms will be affected across the globe. In fish, whole body respiration is traditionally used to estimate aerobic performance via an organism’s minimum and maximum oxygen consumption rates. However, mitochondria play a crucial role in the aerobic cascade and may be a useful surrogate of aerobic performance. To test whether whole body oxygen consumption and mitochondrial capacity are correlated, we estimated whole body metabolic and mitochondrial respiration rates (using permeabilized red muscle fibres) in brook trout ( Salvelinus fontinalis (Mitchill, 1814)) at 10, 15, and 20 °C. Standard metabolic rate increased with acclimation temperature, while maximum rates were less sensitive. All mitochondrial respiration rates increased with acclimation temperature, suggesting that red muscle mitochondrial preparations may correlate to the minimal metabolic demands in this species. When expressed as relative rates of electron flow, the red muscle fibres showed no effect of temperature on mitochondrial coupling efficiency. However, there was a pattern of declining capacity to augment respiration via complex II with increasing temperature with a concomitant increase in the capacity of the phosphorylating system relative to maximal rates of mitochondrial electron flow.

A method to assess the mitochondrial respiratory capacity of complexes I and II from frozen tissue using the Oroboros O2k-FluoRespirometer.

High-resolution respirometry methods allow for the assessment of oxygen consumption by the electron transfer systems within cells, tissue samples, and isolated mitochondrial preparations. As mitochondrial integrity is compromised by the process of cryopreservation, these methods have been limited to fresh samples. Here we present a simple method to assess the activity of mitochondria respiratory complexes I and II in previously cryopreserved murine skeletal muscle tissue homogenates, as well as previously frozen D. melanogaster, as a function of oxygen consumption.

Isolated Mitochondrial Preparations and In organello Assays: A Powerful and Relevant Ex vivo Tool for Assessment of Brain (Patho)physiology.

Mitochondria regulate multiple aspects of neuronal development, physiology, plasticity, and pathology through their regulatory roles in bioenergetic, calcium, redox, and cell survival/death signalling. While several reviews have addressed these different aspects, a comprehensive discussion focussing on the relevance of isolated brain mitochondria and their utilities in neuroscience research has been lacking. This is relevant because the employment of isolated mitochondria rather than their in situ functional evaluation, offers definitive evidence of organelle-specificity, negating the interference from extra mitochondrial cellular factors/signals. This mini-review was designed primarily to explore the commonly employed in organello analytical assays for the assessment of mitochondrial physiology and its dysfunction, with a particular focus on neuroscience research. The authors briefly discuss the methodologies for biochemical isolation of mitochondria, their quality assessment, and cryopres- ervation. Further, the review attempts to accumulate the key biochemical protocols for in organello assessment of a multitude of mitochondrial functions critical for neurophysiology, including assays for bioenergetic activity, calcium and redox homeostasis, and mitochondrial protein translation. The purpose of this review is not to examine each and every method or study related to the functional assessment of isolated brain mitochondria, but rather to assemble the commonly used protocols of in organello mitochondrial research in a single publication. The hope is that this review will provide a suitable platform aiding neuroscientists to choose and apply the required protocols and tools to address their particular mechanistic, diagnostic, or therapeutic question dealing within the confines of the research area of mitochondrial patho-physiology in the neuronal perspective.

Isolation of Mitochondria from Mouse Tissues for Functional Analysis.

Methods for isolating mitochondria from different rodent tissues have been established for decades. Although the general principles for crude mitochondrial preparations are largely shared across tissues - tissue disruption followed by differential centrifugation - critical differences exist for isolation from different tissues to optimize mitochondrial yield and function. This protocol offers a unified resource for preparations of isolated mitochondria from mouse liver, kidney, heart, brain, skeletal muscle, and brown and white adipose tissue suitable for functional analysis.

Disruption of mitochondrial bioenergetics, calcium retention capacity and cell viability caused by D-2-hydroxyglutaric acid in the heart

Accumulation of D-2-hydroxyglutaric acid (D-2-HG) is the biochemical hallmark of D-2-hydroxyglutaric aciduria type I and, particularly, of D-2-hydroxyglutaric aciduria type II (D2HGA2). D2HGA2 is a metabolic inherited disease caused by gain-of-function mutations in the gene isocitrate dehydrogenase 2. It is clinically characterized by neurological abnormalities and a severe cardiomyopathy whose pathogenesis is still poorly established. The present work investigated the potential cardiotoxicity D-2-HG, by studying its in vitro effects on a large spectrum of bioenergetics parameters in heart of young rats and in cultivated H9c2 cardiac myoblasts. D-2-HG impaired cellular respiration in purified mitochondrial preparations and crude homogenates from heart of young rats, as well as in digitonin-permeabilized H9c2 cells. ATP production and the activities of cytochrome c oxidase (complex IV), alpha-ketoglutarate dehydrogenase, citrate synthase and creatine kinase were also inhibited by D-2-HG, whereas the activities of complexes I, II and II-III of the respiratory chain, glutamate, succinate and malate dehydrogenases were not altered. We also found that this organic acid compromised mitochondrial Ca2+ retention capacity in heart mitochondrial preparations and H9c2 myoblasts. Finally, D-2-HG reduced the viability of H9c2 cardiac myoblasts, as determined by the MTT test and by propidium iodide incorporation. Noteworthy, L-2-hydroxyglutaric acid did not change some of these measurements (complex IV and creatine kinase activities) in heart preparations, indicating a selective inhibitory effect of the enantiomer D. In conclusion, it is presumed that D-2-HG-disrupts mitochondrial bioenergetics and Ca2+ retention capacity, which may be involved in the cardiomyopathy commonly observed in D2HGA2.

The Effect of 40-Hz White LED Therapy on Structure-Function of Brain Mitochondrial ATP-Sensitive Ca-Activated Large-Conductance Potassium Channel in Amyloid Beta Toxicity.

Photobiomodulation therapy has become the focus of medical research in many areas such as Alzheimer's disease (AD), because of its modulatory effect on cellular processes through light energy absorption via photoreceptors/chromophores located in the mitochondria. However, there are still many questions around the underlying mechanisms. This study was carried out to unravel whether the function-structure of ATP-sensitive mitoBKCa channels, as crucial components for maintenance of mitochondrial homeostasis, can be altered subsequent to light therapy in AD. Induction of Aβ neurotoxicity in male Wistar rats was done by intracerebroventricular injection of Aβ1-42. After a week, light-treated rats were exposed to 40-Hz white light LEDs, 15min for 7days. Electrophysiological properties of mitoBKCa channel were investigated using a channel incorporated into the bilayer lipid membrane, and mitoBKCa-β2 subunit expression was determined using western blot analysis in Aβ-induced toxicity and light-treated rats. Our results describe that conductance and open probability (Po) of mitoBKCa channel decreased significantly and was accompanied by a Po curve rightward shift in mitochondrial preparation in Aβ-induced toxicity rats. We also showed a significant reduction in expression of mitoBKCa-β2 subunit, which is partly responsible for a leftward shift in BKCa Po curve in low calcium status. Interestingly, we provided evidence of a significant improvement in channel conductance and Po after light therapy. We also found that light therapy improved mitoBKCa-β2 subunit expression, increasing it close to saline group. The current study explains a light therapy improvement in brain mitoBKCa channel function in the Aβ-induced neurotoxicity rat model, an effect that can be linked to increased expression of β2 subunit.

Potential Cardioprotective Effects and Lipid Mediator Differences in Long-Chain Omega-3 Polyunsaturated Fatty Acid Supplemented Mice Given Chemotherapy.

Many commonly used chemotherapies induce mitochondrial dysfunction in cardiac muscle, which leads to cardiotoxicity and heart failure later in life. Dietary long-chain omega-3 polyunsaturated fatty acids (LC n-3 PUFA) have demonstrated cardioprotective function in non-chemotherapy models of heart failure, potentially through the formation of LC n-3 PUFA-derived bioactive lipid metabolites. However, it is unknown whether dietary supplementation with LC n-3 PUFA can protect against chemotherapy-induced cardiotoxicity. To test this, 36 female ovariectomized C57BL/6J mice were randomized in a two-by-two factorial design to either a low (0 g/kg EPA + DHA) or high (12.2 g/kg EPA + DHA) LC n-3 PUFA diet, and received either two vehicle or two chemotherapy (9 mg/kg anthracycline + 90 mg/kg cyclophosphamide) tail vein injections separated by two weeks. Body weight and food intake were measured as well as heart gene expression and fatty acid composition. Heart mitochondria were isolated using differential centrifugation. Mitochondrial isolate oxylipin and N-acylethanolamide levels were measured by mass spectrometry after alkaline hydrolysis. LC n-3 PUFA supplementation attenuated some chemotherapy-induced differences (Myh7, Col3a1) in heart gene expression, and significantly altered various lipid species in cardiac mitochondrial preparations including several epoxy fatty acids [17(18)-EpETE] and N-acylethanolamines (arachidonoylethanolamine, AEA), suggesting a possible functional link between heart lipids and cardiotoxicity.

Disruption of mitochondrial functions involving mitochondrial permeability transition pore opening caused by maleic acid in rat kidney.

Propionic acid (PA) predominantly accumulates in tissues and biological fluids of patients affected by propionic acidemia that may manifest chronic renal failure along development. High urinary excretion of maleic acid (MA) has also been described. Considering that the underlying mechanisms of renal dysfunction in this disorder are poorly known, the present work investigated the effects of PA and MA (1-5mM) on mitochondrial functions and cellular viability in rat kidney and cultured human embryonic kidney (HEK-293) cells. Mitochondrial membrane potential (∆ψm), NAD(P)H content, swelling and ATP production were measured in rat kidney mitochondrial preparations supported by glutamate or glutamate plus malate, in the presence or absence of Ca2+. MTT reduction and propidium iodide (PI) incorporation were also determined in intact renal cells pre-incubated with MA or PA for 24h. MA decreased Δψm and NAD(P)H content and induced swelling in Ca2+-loaded mitochondria either respiring with glutamate or glutamate plus malate. Noteworthy, these alterations were fully prevented by cyclosporin A plus ADP, suggesting the involvement of mitochondrial permeability transition (mPT). MA also markedly inhibited ATP synthesis in kidney mitochondria using the same substrates, implying a strong bioenergetics impairment. In contrast, PA only caused milder changes in these parameters. Finally, MA decreased MTT reduction and increased PI incorporation in intact HEK-293 cells, indicating a possible association between mitochondrial dysfunction and cell death in an intact cell system. It is therefore presumed that the MA-induced disruption of mitochondrial functions involving mPT pore opening may be involved in the chronic renal failure occurring in propionic acidemia.

Dysregulated Mitochondrial Respiration Occurs With Aging

Numerous metabolic changes occur in skeletal muscle with aging. At the crossroads of these changes lies the cellular energy highway, the mitochondrial reticulum. Aging is associated with altered patterns of mitochondrial dynamics and morphology, which are thought to be primarily driven by mitochondrial fragmentation. This fragmentation phenomenon may also lead to altered mitochondrial respiration with aging. We used a mouse model and measured parameters of respiration in muscle mitochondrial preparations to evaluate the hypothesis of aging‐related effects on metabolism and energy substrate partitioning. Mixed skeletal muscle of C57/Bl6 mice (n=32) was excised from single hind‐limbs of young males (YM) (n=8), old males (OM) (n=8), young females (YF) (n=8) and old females (OF) (n=8). Tissues were homogenized in an isotonic solution supplemented with 0.15% protease inhibitor. Mitochondria were isolated by differential centrifugation and their concentrations were determined by BCA analysis. Isolated mitochondria (0.1mg of mitochondria/mL of respiration medium) were then respired using a Clarke‐Type Electrode at 25°C with 100 nM of ADP and either 10 mM Pyruvate+ 2.5 mM Malate (P+M) or 40 uM Palmitoyl‐L‐Carnitine+ 1 mM Malate (PC+M) as substrates. Respiratory Control Ratios (RCR) were calculated as the quotient of State 3 (ADP‐stimulated respiration) and State 4 (recovery rate post ATP synthesis) respiratory rates (State 3/State 4) and compared between substrate and age. ADP to oxygen ratios (P:O) were calculated by dividing the amount of ADP added to the respiratory chamber by the oxygen consumption rate (nmol of O2/mg of mitochondria/minute) of state 3 respiration. RCR in both P+M and PC+M significantly decreased with aging [P+M (p<0.05): YM (4.1±0.9) vs. OM (2.7±1.1); YF (5.1±1.4) vs. OF (3.2±2)] [PC+M (p<0.05): YM (4.2±0.9) vs. OM (2.4±0.7); YF (3.4.±0.5) vs. OF (2.2±0.9)]. P:O in both P+M and PC+M did not significantly change with aging [P+M: (p=0.69): YM (2.9±0.3) vs. OM (2.9±0.2); YF: (p=0.07): (3±0.1) vs. OF (2.9±0.1)] [PC+M:(p=0.65); YM (2.9±0.4) vs. OM (2.9±0.3); (p=0.22): YF (2.9±0.2) vs. OF (2.7±0.3)]. While there were no significant changes in the P:O the age related decreases in the RCR were characterized by a lower capacity to respire derivatives of both CHO and FA. Decreased State 3 respiration and RCR typically corresponds to loss of respiratory capacity and loosening of coupling efficiency. Because exercise increases mitochondrial function and biogenesis it may be prudent to study older animals after exercise training. We plan to further investigate the structural changes in the mitochondrial reticulum and proteome that may be altering mitochondrial function in aging.

QTL mapping suggests that both cytochrome P450-mediated detoxification and target-site resistance are involved in fenbutatin oxide resistance in Tetranychus urticae

The organotin acaricide fenbutatin oxide (FBO) - an inhibitor of mitochondrial ATP-synthase - has been one of the most extensively used acaricides for the control of spider mites, and is still in use today. Resistance against FBO has evolved in many regions around the world but only few studies have investigated the molecular and genetic mechanisms of resistance to organotin acaricides. Here, we found that FBO resistance is polygenic in two genetically distant, highly resistant strains of the spider mite Tetranychus urticae, MAR-AB and MR-VL. To identify the loci underlying FBO resistance, two independent bulked segregant analysis (BSA) based QTL mapping experiments, BSA MAR-AB and BSA MR-VL, were performed. Two QTLs on chromosome 1 were associated with FBO resistance in each mapping experiment. At the second QTL of BSA MAR-AB, several cytochrome P450 monooxygenase (CYP) genes were located, including CYP392E4, CYP392E6 and CYP392E11, the latter being overexpressed in MAR-AB. Synergism tests further implied a role for CYPs in FBO resistance. Subunit c of mitochondrial ATP-synthase was located near the first QTL of both mapping experiments and harbored a unique V89A mutation enriched in the resistant parents and selected BSA populations. Marker-assisted introgression into a susceptible strain demonstrated a moderate but significant effect of the V89A mutation on toxicity of organotin acaricides. The impact of the mutation on organotin inhibition of ATP synthase was also functionally confirmed by ATPase assays on mitochondrial preparations. To conclude, our findings suggest that FBO resistance in the spider mite T. urticae is a complex interplay between CYP-mediated detoxification and target-site resistance.

Analysis of mitochondrial oxygen consumption and hydrogen peroxide release from cardiac mitochondria using electrochemical multi-sensors

Mitochondria are the primary sites of oxygen (O2) consumption and energy metabolism in most cell types, but also produce reactive oxygen species (ROS) that contribute to a wide array of pathological and physiological processes. Accordingly, simultaneous monitoring of mitochondrial ROS release and oxygen consumption rate (OCR) from cells and mitochondrial preparations is an attractive investigative approach in biological research, particularly when sample quantity is scarce. This paper presents the development of a sensitive multi-sensor device capable of measuring ROS production and OCR from biological samples in a single micro-chamber assay. Sensor sensitivities for O2 and hydrogen peroxide (H2O2; the major ROS species released by mitochondria and cells) are 4.32 nA/μM and 54.89 nA/μM, respectively, with limits of detection of 2.9 μM and 58.36 nM, respectively. Proof-of-concept studies in isolated mitochondria from rat cardiac tissue (5 µg protein) demonstrate an expected 3 – 4 fold increase in H2O2 release over the basal rate following addition of respiratory substrates, with a comparatively small change in OCR. The subsequent addition of adenosine diphosphate (ADP) decreased H2O2 release by 73% (p < 0.01) and increased OCR by 168% (p < 0.01), consistent with established shifts in mitochondrial membrane potential and electron flow from an ADP-limited (State 4) to ADP-stimulated (State 3) respiratory state. These studies validate the results from the use of a novel multi-sensor device capable of monitoring OCR and H2O2 simultaneously in scarce biological samples, with potential utility in the non-destructive integrative study of cellular metabolism and mitochondrial function.

Measurement of Mitochondrial (Dys)Function in Cellular Systems Using Electron Paramagnetic Resonance (EPR): Oxygen Consumption Rate and Superoxide Production.

The oxygen consumption rate (OCR) and superoxide production are crucial when assessing mitochondrial function and/or dysfunction. EPR spectroscopy allows the measurement of both components either independently or simultaneously in a same cellular or mitochondrial preparation. OCR determination using EPR oximetry is based on the change in EPR linewidth of a paramagnetic oxygen sensing probe (a perdeuterated nitroxide) in the presence of oxygen consuming cells in a closed system. Superoxide production can be monitored by the oxidation of cyclic hydroxylamines into nitroxides. The contribution of superoxide to the nitroxide formation is deduced from experiments in the presence and in the absence of SOD and PEG-SOD as appropriate controls.

Measurement of Futile Creatine Cycling Using Respirometry.

Thermogenic adipose tissue plays a vital function in regulating whole-body energy expenditure and nutrient homeostasis due to its capacity to dissipate chemical energy as heat, in a process called non-shivering thermogenesis. A reduction of creatine levels in adipocytes impairs thermogenic capacity and promotes diet-induced obesityKazak et al, Cell 163, 643-55, 2015; Kazak et al, Cell Metab 26, 660-671.e3, 2017; Kazak et al, Nat Metab 1, 360-370, 2019). Mechanistically, thermogenic respiration can be promoted by the liberation of an excess quantity of ADP that is dependent on addition of creatine. A model of a two-enzyme system, which we term the Futile Creatine Cycle, has been posited to support this thermogenic action of creatine. Futile creatine cycling can be monitored in purified mitochondrial preparations wherein creatine-dependent liberation of ADP is monitored through the measurement of oxygen consumption under ADP-limiting conditions. The current model proposes that, in thermogenic fat cells, mitochondria-targeted creatine kinase B (CKB) uses mitochondrial-derived ATP to phosphorylate creatine (Rahbani JF, Nature 590, 480-485, 2021). The creatine kinase reaction generates phosphocreatine and ADP, and ADP stimulates respiration. Next, a pool of mitochondrial phosphocreatine is directly hydrolyzed by a phosphatase, to regenerate creatine. The liberated creatine can then engage mitochondrial CKB to trigger another round of this cycle to support ADP-dependent respiration. In this model, the coordinated action of creatine phosphorylation and phosphocreatine hydrolysis triggers a futile cycle that produces a molar excess of mitochondrial ADP to promote thermogenic respiration (Rahbani JF, Nature 590, 480-485, 2021; Kazak and Cohen, Nat Rev Endocrinol 16, 421-436, 2020). Here, we provide a detailed method to perform respiratory measurements on isolated mitochondria and calculate the stoichiometry of creatine-dependent ADP liberation. This method provides a direct measure of the futile creatine cycle.