Your search keyword '"reverse electron transport"' showing total 100 results

1. Formation of I2+III2 supercomplex rescues respiratory chain defects

Author

Liang, Chao, Padavannil, Abhilash, Zhang, Shan, Beh, Sheryl, Robinson, David R.L., Meisterknecht, Jana, Cabrera-Orefice, Alfredo, Koves, Timothy R., Watanabe, Chika, Watanabe, Miyuki, Illescas, María, Lim, Radiance, Johnson, Jordan M., Ren, Shuxun, Wu, Ya-Jun, Kappei, Dennis, Ghelli, Anna Maria, Funai, Katsuhiko, Osaka, Hitoshi, Muoio, Deborah, Ugalde, Cristina, Wittig, Ilka, Stroud, David A., Letts, James A., and Ho, Lena

Published

2025

2. Mitochondrial complex I: the key to sustained microglia activation and neuroinflammation maintenance

Author

Hua Wang, Sheng-Yuan Yu, Sofus Nielsen, Xing Wang, and Wei-Wei Zhao

Subjects

Mitochondrial complex I, Neuroinflammation, Multiple sclerosis, Reverse electron transport, Microglial activation, Medicine (General), R5-920, Military Science

Published

2024

3. A model of mitochondrial superoxide production during ischaemia-reperfusion injury for therapeutic development and mechanistic understanding

Author

Annabel Sorby-Adams, Tracy A. Prime, Jan Lj Miljkovic, Hiran A. Prag, Thomas Krieg, and Michael P. Murphy

Subjects

Ischaemia-reperfusion injury, Mitochondria, Succinate, Malonate, Complex I, Reverse electron transport, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Ischaemia-reperfusion (IR) injury is the paradoxical consequence of the rapid restoration of blood flow to an ischaemic organ. Although reperfusion is essential for tissue survival in conditions such as myocardial infarction and stroke, the excessive production of mitochondrial reactive oxygen species (ROS) upon reperfusion initiates the oxidative damage that underlies IR injury, by causing cell death and inflammation. This ROS production is caused by an accumulation of the mitochondrial metabolite succinate during ischaemia, followed by its rapid oxidation upon reperfusion by succinate dehydrogenase (SDH), driving superoxide production at complex I by reverse electron transport. Inhibitors of SDH, such as malonate, show therapeutic potential by decreasing succinate oxidation and superoxide production upon reperfusion. To better understand the mechanism of mitochondrial ROS production upon reperfusion and to assess potential therapies, we set up an in vitro model of IR injury. For this, isolated mitochondria were incubated anoxically with succinate to mimic ischaemia and then rapidly reoxygenated to replicate reperfusion, driving a burst of ROS formation. Using this system, we assess the factors that contribute to the magnitude of mitochondrial ROS production in heart, brain, and kidney mitochondria, as well as screening for inhibitors of succinate oxidation with therapeutic potential.

Published

2024

4. Mitochondrial complex I: the key to sustained microglia activation and neuroinflammation maintenance.

Author

Wang, Hua, Yu, Sheng-Yuan, Nielsen, Sofus, Wang, Xing, and Zhao, Wei-Wei

Subjects

CELL metabolism, CENTRAL nervous system diseases, MYELOID cells, THERAPEUTICS, TUMOR necrosis factors

Abstract

A study published in the journal Military Medical Research explores the role of mitochondrial complex I (CI) in sustaining chronic neuroinflammation, specifically in multiple sclerosis (MS). The study suggests that CI activity, through a mechanism called reverse electron transport (RET), generates reactive oxygen species (ROS) in microglia, leading to the perpetuation of inflammation in the central nervous system (CNS). The continuous activation of microglia caused by CI contributes to the accumulation of myeloid cells at lesion sites, further exacerbating CNS pathology. Inhibiting CI activity shows promise as a therapeutic approach for neuroinflammatory diseases. However, further research is needed to fully understand the regulatory mechanisms and signaling pathways involved. The study highlights the potential for developing personalized treatments and biomarkers for early detection and monitoring of neuroinflammatory diseases. [Extracted from the article]

Published

2024

5. Preventing mitochondrial reverse electron transport as a strategy for cardioprotection.

Author

Prag, Hiran A., Murphy, Michael P., and Krieg, Thomas

Subjects

*ELECTRON transport, *MITOCHONDRIA, *MYOCARDIAL infarction

Abstract

In the context of myocardial infarction, the burst of superoxide generated by reverse electron transport (RET) at complex I in mitochondria is a crucial trigger for damage during ischaemia/reperfusion (I/R) injury. Here we outline the necessary conditions for superoxide production by RET at complex I and how it can occur during reperfusion. In addition, we explore various pathways that are implicated in generating the conditions for RET to occur and suggest potential therapeutic strategies to target RET, aiming to achieve cardioprotection. [ABSTRACT FROM AUTHOR]

Published

2023

6. Reverse electron transfer is activated during aging and contributes to aging and age‐related disease.

Author

Rimal, Suman, Tantray, Ishaq, Li, Yu, Pal Khaket, Tejinder, Li, Yanping, Bhurtel, Sunil, Li, Wen, Zeng, Cici, and Lu, Bingwei

Abstract

Mechanisms underlying the depletion of NAD+ and accumulation of reactive oxygen species (ROS) in aging and age‐related disorders remain poorly defined. We show that reverse electron transfer (RET) at mitochondrial complex I, which causes increased ROS production and NAD+ to NADH conversion and thus lowered NAD+/NADH ratio, is active during aging. Genetic or pharmacological inhibition of RET decreases ROS production and increases NAD+/NADH ratio, extending the lifespan of normal flies. The lifespan‐extending effect of RET inhibition is dependent on NAD+‐dependent Sirtuin, highlighting the importance of NAD+/NADH rebalance, and on longevity‐associated Foxo and autophagy pathways. RET and RET‐induced ROS and NAD+/NADH ratio changes are prominent in human induced pluripotent stem cell (iPSC) model and fly models of Alzheimer's disease (AD). Genetic or pharmacological inhibition of RET prevents the accumulation of faulty translation products resulting from inadequate ribosome‐mediated quality control, rescues relevant disease phenotypes, and extends the lifespan of Drosophila and mouse AD models. Deregulated RET is therefore a conserved feature of aging, and inhibition of RET may open new therapeutic opportunities in the context of aging and age‐related diseases including AD. Synopsis: Reverse electron transport (RET) at mitochondrial complex I generates reactive oxygen species (ROS) and reduces NAD+/NADH ratio. Inhibition of RET genetically or pharmacologically extends animal lifespan and ameliorates Alzheimer's disease‐related phenotypes. RET is activated in aged Drosophila and Drosophila models of Alzheimer's disease (AD)Inhibition of RET using a small molecule drug CPT or by knocking down its target mitochondrial complex I subunit NDUFS3 extends lifespan in Drosophila and mice.Inhibition of RET rescues AD‐related disease phenotypes in Drosophila and mouse modelsRET is also active in human iPSC models of AD. [ABSTRACT FROM AUTHOR]

Published

2023

7. Total and reduced/oxidized forms of coenzyme Q10 in fibroblasts of patients with mitochondrial disease

Author

Chika Watanabe, Hitoshi Osaka, Miyuki Watanabe, Akihiko Miyauchi, Eriko F. Jimbo, Takeshi Tokuyama, Hideki Uosaki, Yoshihito Kishita, Yasushi Okazaki, Takanori Onuki, Tomohiro Ebihara, Kenichi Aizawa, Kei Murayama, Akira Ohtake, and Takanori Yamagata

Subjects

Mitochondrial disease, Primary coenzyme Q10 deficiency, Coenzyme Q10, Reduced/total CoQ10, Forward electron transport, Reverse electron transport, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Coenzyme Q10 (CoQ10) is involved in ATP production through electron transfer in the mitochondrial respiratory chain complex. CoQ10 receives electrons from respiratory chain complex I and II to become the reduced form, and then transfers electrons at complex III to become the oxidized form. The redox state of CoQ10 has been reported to be a marker of the mitochondrial metabolic state, but to our knowledge, no reports have focused on the individual quantification of reduced and oxidized CoQ10 or the ratio of reduced to total CoQ10 (reduced/total CoQ10) in patients with mitochondrial diseases.We measured reduced and oxidized CoQ10 in skin fibroblasts from 24 mitochondrial disease patients, including 5 primary CoQ10 deficiency patients and 10 respiratory chain complex deficiency patients, and determined the reduced/total CoQ10 ratio.In primary CoQ10 deficiency patients, total CoQ10 levels were significantly decreased, however, the reduced/total CoQ10 ratio was not changed. On the other hand, in mitochondrial disease patients other than primary CoQ10 deficiency patients, total CoQ10 levels did not decrease. However, the reduced/total CoQ10 ratio in patients with respiratory chain complex IV and V deficiency was higher in comparison to those with respiratory chain complex I deficiency.Measurement of CoQ10 in fibroblasts proved useful for the diagnosis of primary CoQ10 deficiency. In addition, the reduced/total CoQ10 ratio may reflect the metabolic status of mitochondrial disease.

Published

2023

8. Dimethyl fumarate inhibits necroptosis and alleviates systemic inflammatory response syndrome by blocking the RIPK1-RIPK3-MLKL axis

Author

Fu-li Shi, Li-sha Yuan, Tak-sui Wong, Qing Li, Ya-ping Li, Rong Xu, Yi-ping You, Tao Yuan, Hong-rui zhang, Zi-jian Shi, Qing-bing Zha, Bo Hu, Xian-hui He, and Dong-yun Ouyang

Subjects

Dimethyl fumarate, Necroptosis, Reverse electron transport, RIPK3, MLKL, Systemic inflammatory response syndrome, Therapeutics. Pharmacology, RM1-950

Abstract

Necroptosis has been implicated in various inflammatory diseases including tumor-necrosis factor-α (TNF-α)-induced systemic inflammatory response syndrome (SIRS). Dimethyl fumarate (DMF), a first-line drug for treating relapsing-remitting multiple sclerosis (RRMS), has been shown to be effective against various inflammatory diseases. However, it is still unclear whether DMF can inhibit necroptosis and confer protection against SIRS. In this study, we found that DMF significantly inhibited necroptotic cell death in macrophages induced by different necroptotic stimulations. Both the autophosphorylation of receptor-interacting serine/threonine kinase 1 (RIPK1) and RIPK3 and the downstream phosphorylation and oligomerization of MLKL were robustly suppressed by DMF. Accompanying the suppression of necroptotic signaling, DMF blocked the mitochondrial reverse electron transport (RET) induced by necroptotic stimulation, which was associated with its electrophilic property. Several well-known anti-RET reagents also markedly inhibited the activation of the RIPK1-RIPK3-MLKL axis accompanied by decreased necrotic cell death, indicating a critical role of RET in necroptotic signaling. DMF and other anti-RET reagents suppressed the ubiquitination of RIPK1 and RIPK3, and they attenuated the formation of necrosome. Moreover, oral administration of DMF significantly alleviated the severity of TNF-α-induced SIRS in mice. Consistent with this, DMF mitigated TNF-α-induced cecal, uterine, and lung damage accompanied by diminished RIPK3-MLKL signaling. Collectively, DMF represents a new necroptosis inhibitor that suppresses the RIPK1-RIPK3-MLKL axis through blocking mitochondrial RET. Our study highlights DMF’s potential therapeutic applications for treating SIRS-associated diseases.

Published

2023

9. Nutritional Diversity Amongst Bacteria: Chemolithotrophy and Phototrophy

Author

Gupta, Rani, Gupta, Namita, Aggarwal, Sunita, Gupta, Rani, and Gupta, Namita

Published

2021

10. Melatonin drives apoptosis in head and neck cancer by increasing mitochondrial ROS generated via reverse electron transport.

Author

Florido, Javier, Martinez‐Ruiz, Laura, Rodriguez‐Santana, César, López‐Rodríguez, Alba, Hidalgo‐Gutiérrez, Agustín, Cottet‐Rousselle, Cécile, Lamarche, Frédéric, Schlattner, Uwe, Guerra‐Librero, Ana, Aranda‐Martínez, Paula, Acuña‐Castroviejo, Darío, López, Luis C., and Escames, Germaine

Subjects

*HEAD & neck cancer, *ELECTRON transport, *MELATONIN, *OXIDASES, *REACTIVE oxygen species, *MITOCHONDRIA, *FREE radicals

Abstract

The oncostatic effects of melatonin correlate with increased reactive oxygen species (ROS) levels, but how melatonin induces this ROS generation is unknown. In the present study, we aimed to elucidate the two seemingly opposing actions of melatonin regarding its relationship with free radicals. We analyzed the effects of melatonin on head and neck squamous cell carcinoma cell lines (Cal‐27 and SCC‐9), which were treated with 0.5 or 1 mM melatonin. We further examined the potential effects of melatonin to induce ROS and apoptosis in Cal‐27 xenograft mice. Here we report that melatonin mediates apoptosis in head and neck cancer by driving mitochondrial reverse electron transport (RET) to induce ROS production. Melatonin‐induced changes in tumoral metabolism led to increased mitochondrial activity, which, in turn, induced ROS‐dependent mitochondrial uncoupling. Interestingly, mitochondrial complex inhibitors, including rotenone, abolished the ROS elevation indicating that melatonin increased ROS generation via RET. Melatonin also increased membrane potential and CoQ10H2/CoQ10 ratio to elevate mitochondrial ROS production, which are essential conditions for RET. We found that genetic manipulation of cancer cells with alternative oxidase, which transfers electrons from QH2 to oxygen, inhibited melatonin‐induced ROS generation, and apoptosis. RET restored the melatonin‐induced oncostatic effect, highlighting the importance of RET as the site of ROS production. These results illustrate that RET and ROS production are crucial factors in melatonin's effects in cancer cells and establish the dual effect of melatonin in protecting normal cells and inducing apoptosis in cancer cells. [ABSTRACT FROM AUTHOR]

Published

2022

11. Mitochondrial ROS signalling requires uninterrupted electron flow and is lost during ageing in flies.

Author

Graham, Charlotte, Stefanatos, Rhoda, Yek, Angeline E. H., Spriggs, Ruth V., Loh, Samantha H. Y., Uribe, Alejandro Huerta, Zhang, Tong, Martins, L. Miguel, Maddocks, Oliver D. K., Scialo, Filippo, and Sanz, Alberto

Subjects

ELECTRON transport, ELECTRONS, FRUIT flies, REACTIVE oxygen species, OLDER people, LOW-calorie diet, POPULATION aging

Abstract

Mitochondrial reactive oxygen species (mtROS) are cellular messengers essential for cellular homeostasis. In response to stress, reverse electron transport (RET) through respiratory complex I generates high levels of mtROS. Suppression of ROS production via RET (ROS-RET) reduces survival under stress, while activation of ROS-RET extends lifespan in basal conditions. Here, we demonstrate that ROS-RET signalling requires increased electron entry and uninterrupted electron flow through the electron transport chain (ETC). We find that in old fruit flies, ROS-RET is abolished when electron flux is decreased and that their mitochondria produce consistently high levels of mtROS. Finally, we demonstrate that in young flies, limiting electron exit, but not entry, from the ETC phenocopies mtROS generation observed in old individuals. Our results elucidate the mechanism by which ROS signalling is lost during ageing. [ABSTRACT FROM AUTHOR]

Published

2022

12. Pyruvate Supports RET-Dependent Mitochondrial ROS Production to Control Mycobacterium avium Infection in Human Primary Macrophages.

Author

Røst, Lisa Marie, Louet, Claire, Bruheim, Per, Flo, Trude Helen, and Gidon, Alexandre

Subjects

MYCOBACTERIUM avium, MYCOBACTERIAL diseases, WARBURG Effect (Oncology), PRODUCTION control, PYRUVATES, KREBS cycle, MITOCHONDRIA

Abstract

Macrophages deploy a variety of antimicrobial programs to contain mycobacterial infection. Upon activation, they undergo extensive metabolic reprogramming to meet an increase in energy demand, but also to support immune effector functions such as secretion of cytokines and antimicrobial activities. Here, we report that mitochondrial import of pyruvate is linked to production of mitochondrial ROS and control of Mycobacterium avium (M. avium) infection in human primary macrophages. Using chemical inhibition, targeted mass spectrometry and single cell image analysis, we showed that macrophages infected with M. avium switch to aerobic glycolysis without any major imbalances in the tricarboxylic acid cycle volume or changes in the energy charge. Instead, we found that pyruvate import contributes to hyperpolarization of mitochondria in infected cells and increases production of mitochondrial reactive oxygen species by the complex I via reverse electron transport, which reduces the macrophage burden of M. avium. While mycobacterial infections are extremely difficult to treat and notoriously resistant to antibiotics, this work stresses out that compounds specifically inducing mitochondrial reactive oxygen species could present themself as valuable adjunct treatments. [ABSTRACT FROM AUTHOR]

Published

2022

13. Pyruvate Supports RET-Dependent Mitochondrial ROS Production to Control Mycobacterium avium Infection in Human Primary Macrophages

Author

Lisa Marie Røst, Claire Louet, Per Bruheim, Trude Helen Flo, and Alexandre Gidon

Subjects

Mycobacterium avium infection, innate immunity, human primary macrophages, glycolysis, pyruvate, reverse electron transport, Immunologic diseases. Allergy, RC581-607

Abstract

Macrophages deploy a variety of antimicrobial programs to contain mycobacterial infection. Upon activation, they undergo extensive metabolic reprogramming to meet an increase in energy demand, but also to support immune effector functions such as secretion of cytokines and antimicrobial activities. Here, we report that mitochondrial import of pyruvate is linked to production of mitochondrial ROS and control of Mycobacterium avium (M. avium) infection in human primary macrophages. Using chemical inhibition, targeted mass spectrometry and single cell image analysis, we showed that macrophages infected with M. avium switch to aerobic glycolysis without any major imbalances in the tricarboxylic acid cycle volume or changes in the energy charge. Instead, we found that pyruvate import contributes to hyperpolarization of mitochondria in infected cells and increases production of mitochondrial reactive oxygen species by the complex I via reverse electron transport, which reduces the macrophage burden of M. avium. While mycobacterial infections are extremely difficult to treat and notoriously resistant to antibiotics, this work stresses out that compounds specifically inducing mitochondrial reactive oxygen species could present themself as valuable adjunct treatments.

Published

2022

14. Cooling Uncouples Differentially ROS Production from Respiration and Ca 2+ Homeostasis Dynamic in Brain and Heart Mitochondria.

Author

Stevic, Neven, Maalouf, Jennifer, Argaud, Laurent, Gallo-Bona, Noëlle, Lo Grasso, Mégane, Gouriou, Yves, Gomez, Ludovic, Crola Da Silva, Claire, Ferrera, René, Ovize, Michel, Cour, Martin, and Bidaux, Gabriel

Subjects

*MYOCARDIAL reperfusion, *HOMEOSTASIS, *MITOCHONDRIA, *RESPIRATION, *REACTIVE oxygen species, *COOLING

Abstract

Hypothermia provides an effective neuro and cardio-protection in clinical settings implying ischemia/reperfusion injury (I/R). At the onset of reperfusion, succinate-induced reactive oxygen species (ROS) production, impaired oxidative phosphorylation (OXPHOS), and decreased Ca2+ retention capacity (CRC) concur to mitochondrial damages. We explored the effects of temperature from 6 to 37 °C on OXPHOS, ROS production, and CRC, using isolated mitochondria from mouse brain and heart. Oxygen consumption and ROS production was gradually inhibited when cooling from 37 to 6 °C in brain mitochondria (BM) and heart mitochondria (HM). The decrease in ROS production was gradual in BM but steeper between 31 and 20 °C in HM. In respiring mitochondria, the gradual activation of complex II, in addition of complex I, dramatically enhanced ROS production at all temperatures without modifying respiration, likely because of ubiquinone over-reduction. Finally, CRC values were linearly increased by cooling in both BM and HM. In BM, the Ca2+ uptake rate by the mitochondrial calcium uniporter (MCU) decreased by 2.7-fold between 25 and 37 °C, but decreased by 5.7-fold between 25 and 37 °C in HM. In conclusion, mild cold (25–37 °C) exerts differential inhibitory effects by preventing ROS production, by reverse electron transfer (RET) in BM, and by reducing MCU-mediated Ca2+ uptake rate in BM and HM. [ABSTRACT FROM AUTHOR]

Published

2022

15. Identifying Site-Specific Superoxide and Hydrogen Peroxide Production Rates From the Mitochondrial Electron Transport System Using a Computational Strategy.

Author

Duong, Quynh V, Levitsky, Yan, Dessinger, Maria J, Strubbe-Rivera, Jasiel O, and Bazil, Jason N

Subjects

*ELECTRON transport, *UBIQUINONES, *NAD (Coenzyme), *MITOCHONDRIA, *REACTIVE oxygen species, *SUPEROXIDES, *CELL communication

Abstract

Mitochondrial reactive oxygen species (ROS) play important roles in cellular signaling; however, certain pathological conditions such as ischemia/reperfusion (I/R) injury disrupt ROS homeostasis and contribute to cell death. A major impediment to developing therapeutic measures against oxidative stress-induced cellular damage is the lack of a quantitative framework to identify the specific sources and regulatory mechanisms of mitochondrial ROS production. We developed a thermodynamically consistent, mass-and-charge balanced, kinetic model of mitochondrial ROS homeostasis focused on redox sites of electron transport chain complexes I, II, and III. The model was calibrated and corroborated using comprehensive data sets relevant to ROS homeostasis. The model predicts that complex I ROS production dominates other sources under conditions favoring a high membrane potential with elevated nicotinamide adenine dinucleotide (NADH) and ubiquinol (QH2) levels. In general, complex I contributes to significant levels of ROS production under pathological conditions, while complexes II and III are responsible for basal levels of ROS production, especially when QH2 levels are elevated. The model also reveals that hydrogen peroxide production by complex I underlies the non-linear relationship between ROS emission and O2 at low O2 concentrations. Lastly, the model highlights the need to quantify scavenging system activity under different conditions to establish a complete picture of mitochondrial ROS homeostasis. In summary, we describe the individual contributions of the electron transport system complex redox sites to total ROS emission in mitochondria respiring under various combinations of NADH- and Q-linked respiratory fuels under varying workloads. Graphical Abstract [ABSTRACT FROM AUTHOR]

Published

2021

16. Mitochondrial Reactive Oxygen Species Regulate Immune Responses of Macrophages to Aspergillus fumigatus

Author

Remi Hatinguais, Arnab Pradhan, Gordon D. Brown, Alistair J. P. Brown, Adilia Warris, and Elena Shekhova

Subjects

macrophages, reverse electron transport, reactive oxygen species, mitochondria, Aspegillus fumigatus, cytokines, Immunologic diseases. Allergy, RC581-607

Abstract

Reactive Oxygen Species (ROS) are highly reactive molecules that can induce oxidative stress. For instance, the oxidative burst of immune cells is well known for its ability to inhibit the growth of invading pathogens. However, ROS also mediate redox signalling, which is important for the regulation of antimicrobial immunity. Here, we report a crucial role of mitochondrial ROS (mitoROS) in antifungal responses of macrophages. We show that mitoROS production rises in murine macrophages exposed to swollen conidia of the fungal pathogen Aspergillus fumigatus compared to untreated macrophages, or those treated with resting conidia. Furthermore, the exposure of macrophages to swollen conidia increases the activity of complex II of the respiratory chain and raises mitochondrial membrane potential. These alterations in mitochondria of infected macrophages suggest that mitoROS are produced via reverse electron transport (RET). Significantly, preventing mitoROS generation via RET by treatment with rotenone, or a suppressor of site IQ electron leak, S1QEL1.1, lowers the production of pro-inflammatory cytokines TNF-α and IL-1β in macrophages exposed to swollen conidia of A. fumigatus. Rotenone and S1QEL1.1 also reduces the fungicidal activity of macrophages against swollen conidia. Moreover, we have established that elevated recruitment of NADPH oxidase 2 (NOX2, also called gp91phox) to the phagosomal membrane occurs prior to the increase in mitoROS generation. Using macrophages from gp91phox-/- mice, we have further demonstrated that NOX2 is required to regulate cytokine secretion by RET-associated mitoROS in response to infection with swollen conidia. Taken together, these observations demonstrate the importance of RET-mediated mitoROS production in macrophages infected with A. fumigatus.

Published

2021

17. Mitochondrial Reactive Oxygen Species Regulate Immune Responses of Macrophages to Aspergillus fumigatus.

Author

Hatinguais, Remi, Pradhan, Arnab, Brown, Gordon D., Brown, Alistair J. P., Warris, Adilia, and Shekhova, Elena

Subjects

REACTIVE oxygen species, ASPERGILLUS fumigatus, IMMUNE response, MACROPHAGES, IMMUNOREGULATION

Abstract

Reactive Oxygen Species (ROS) are highly reactive molecules that can induce oxidative stress. For instance, the oxidative burst of immune cells is well known for its ability to inhibit the growth of invading pathogens. However, ROS also mediate redox signalling, which is important for the regulation of antimicrobial immunity. Here, we report a crucial role of mitochondrial ROS (mitoROS) in antifungal responses of macrophages. We show that mitoROS production rises in murine macrophages exposed to swollen conidia of the fungal pathogen Aspergillus fumigatus compared to untreated macrophages, or those treated with resting conidia. Furthermore, the exposure of macrophages to swollen conidia increases the activity of complex II of the respiratory chain and raises mitochondrial membrane potential. These alterations in mitochondria of infected macrophages suggest that mitoROS are produced via reverse electron transport (RET). Significantly, preventing mitoROS generation via RET by treatment with rotenone, or a suppressor of site IQ electron leak, S1QEL1.1, lowers the production of pro-inflammatory cytokines TNF-α and IL-1β in macrophages exposed to swollen conidia of A. fumigatus. Rotenone and S1QEL1.1 also reduces the fungicidal activity of macrophages against swollen conidia. Moreover, we have established that elevated recruitment of NADPH oxidase 2 (NOX2, also called gp91phox) to the phagosomal membrane occurs prior to the increase in mitoROS generation. Using macrophages from gp91phox-/- mice, we have further demonstrated that NOX2 is required to regulate cytokine secretion by RET-associated mitoROS in response to infection with swollen conidia. Taken together, these observations demonstrate the importance of RET-mediated mitoROS production in macrophages infected with A. fumigatus. [ABSTRACT FROM AUTHOR]

Published

2021

18. Mitochondrial complex I derived ROS regulate stress adaptation in Drosophila melanogaster

Author

Filippo Scialò, Ashwin Sriram, Rhoda Stefanatos, Ruth V. Spriggs, Samantha H.Y. Loh, L. Miguel Martins, and Alberto Sanz

Subjects

Heat stress, Reverse electron transport, Complex I, Reactive oxygen species, Alternative oxidase, AOX, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Reactive Oxygen Species (ROS) are essential cellular messengers required for cellular homeostasis and regulate the lifespan of several animal species. The main site of ROS production is the mitochondrion, and within it, respiratory complex I (CI) is the main ROS generator. ROS produced by CI trigger several physiological responses that are essential for the survival of neurons, cardiomyocytes and macrophages. Here, we show that CI produces ROS when electrons flow in either the forward (Forward Electron Transport, FET) or reverse direction (Reverse Electron Transport, RET). We demonstrate that ROS production via RET (ROS-RET) is activated under thermal stress conditions and that interruption of ROS-RET production, through ectopic expression of the alternative oxidase AOX, attenuates the activation of pro-survival pathways in response to stress. Accordingly, we find that both suppressing ROS-RET signalling or decreasing levels of mitochondrial H2O2 by overexpressing mitochondrial catalase (mtCAT), reduces survival dramatically in flies under stress. Our results uncover a specific ROS signalling pathway where hydrogen peroxide (H2O2) generated by CI via RET is required to activate adaptive mechanisms, maximising survival under stress conditions.

Published

2020

19. S1QELs suppress mitochondrial superoxide/hydrogen peroxide production from site IQ without inhibiting reverse electron flow through Complex I.

Author

Wong, Hoi-Shan, Monternier, Pierre-Axel, and Brand, Martin D.

Subjects

*HYDROGEN production, *ELECTRON transport, *ELECTRONS, *SUPEROXIDES, *HYDROGEN peroxide, *INTELLIGENCE levels, *SMALL molecules

Abstract

Mitochondria are important sources of superoxide and hydrogen peroxide in cell signaling and disease. In particular, superoxide/hydrogen peroxide production during reverse electron transport from ubiquinol to NAD+ though Complex I is implicated in several physiological and pathological processes. S1QELs are small molecules that suppress superoxide/hydrogen peroxide production at Complex I without affecting forward electron transport. Their mechanism of action is disputed. To test different mechanistic models, we compared the effects of two inhibitors of Complex I electron transport (piericidin A and rotenone) and two S1QELs from different chemical families on superoxide/hydrogen peroxide production and electron transport by Complex I in isolated mitochondria. Piericidin A and rotenone (and S1QEL1.1 at higher concentrations) prevented superoxide/hydrogen peroxide production from sites I Q and I F in Complex I by inhibiting reverse electron transport into the complex. S1QELs decreased the potency of electron transport inhibition by piericidin A and rotenone, suggesting that S1QELs bind directly to Complex I. S1QEL2.1 (and S1QEL1.1 at lower concentrations) suppressed site I Q without affecting reverse electron transport or site I F , showing that sites I Q and I F are distinct, and that S1QELs do not work simply by decreasing reverse electron transport to site I F (or site I Q). S1QELs did not affect the reduction of NAD+ or the rate of site I F driven by reverse electron transport, therefore they do not alter the driving forces for reverse electron transport and that is not how they suppress site I Q. We conclude that S1QELs bind to Complex I to influence the conformation of the piericidin A and rotenone binding sites and directly suppress superoxide/hydrogen peroxide production at site I Q , which is a separate site from site I F. Image 1 • S1QELs bind directly to mitochondrial Complex I. • Sites I Q and I F are distinct. • S1QELs do not alter the driving forces for reverse electron transport. • S1QELs do not suppress O 2 .-/H 2 O 2 production by decreasing reverse electron transport. [ABSTRACT FROM AUTHOR]

Published

2019

20. Tracking Electron Uptake from a Cathode into Shewanella Cells: Implications for Energy Acquisition from Solid-Substrate Electron Donors

Author

Annette R. Rowe, Pournami Rajeev, Abhiney Jain, Sahand Pirbadian, Akihiro Okamoto, Jeffrey A. Gralnick, Mohamed Y. El-Naggar, and Kenneth H. Nealson

Subjects

electron uptake, energy acquisition, reverse electron transport, Shewanella, systems biology, Microbiology, QR1-502

Abstract

ABSTRACT While typically investigated as a microorganism capable of extracellular electron transfer to minerals or anodes, Shewanella oneidensis MR-1 can also facilitate electron flow from a cathode to terminal electron acceptors, such as fumarate or oxygen, thereby providing a model system for a process that has significant environmental and technological implications. This work demonstrates that cathodic electrons enter the electron transport chain of S. oneidensis when oxygen is used as the terminal electron acceptor. The effect of electron transport chain inhibitors suggested that a proton gradient is generated during cathode oxidation, consistent with the higher cellular ATP levels measured in cathode-respiring cells than in controls. Cathode oxidation also correlated with an increase in the cellular redox (NADH/FMNH2) pool determined with a bioluminescence assay, a proton uncoupler, and a mutant of proton-pumping NADH oxidase complex I. This work suggested that the generation of NADH/FMNH2 under cathodic conditions was linked to reverse electron flow mediated by complex I. A decrease in cathodic electron uptake was observed in various mutant strains, including those lacking the extracellular electron transfer components necessary for anodic-current generation. While no cell growth was observed under these conditions, here we show that cathode oxidation is linked to cellular energy acquisition, resulting in a quantifiable reduction in the cellular decay rate. This work highlights a potential mechanism for cell survival and/or persistence on cathodes, which might extend to environments where growth and division are severely limited. IMPORTANCE The majority of our knowledge of the physiology of extracellular electron transfer derives from studies of electrons moving to the exterior of the cell. The physiological mechanisms and/or consequences of the reverse processes are largely uncharacterized. This report demonstrates that when coupled to oxygen reduction, electrode oxidation can result in cellular energy acquisition. This respiratory process has potentially important implications for how microorganisms persist in energy-limited environments, such as reduced sediments under changing redox conditions. From an applied perspective, this work has important implications for microbially catalyzed processes on electrodes, particularly with regard to understanding models of cellular conversion of electrons from cathodes to microbially synthesized products.

Published

2018

21. Mitochondrial ROS signalling requires uninterrupted electron flow and is lost during ageing in flies

Author

Graham, Charlotte, Stefanatos, Rhoda, Yek, Angeline E.H., Spriggs, Ruth V., Loh, Samantha H.Y., Huerta Uribe, Alejandro, Zhang, Tong, Martins, L. Miguel, Maddocks, Oliver D.K., Scialo, Filippo, Sanz, Alberto, Graham, C., Stefanatos, R., Yek, A. E. H., Spriggs, R. V., Loh, S. H. Y., Uribe, A. H., Zhang, T., Martins, L. M., Maddocks, O. D. K., Scialo, F., Sanz, A., Sanz, Alberto [0000-0003-2149-1753], and Apollo - University of Cambridge Repository

Subjects

Reverse electron transport, Aging, endocrine system diseases, Diptera, Electrons, Complex IV, Mitochondria, Electron Transport, Ageing, Complex I, Reactive oxygen specie, Animals, Drosophila, Geriatrics and Gerontology, Reactive Oxygen Species

Abstract

Mitochondrial reactive oxygen species (mtROS) are cellular messengers essential for cellular homeostasis. In response to stress, reverse electron transport (RET) through respiratory complex I generates high levels of mtROS. Suppression of ROS production via RET (ROS-RET) reduces survival under stress, while activation of ROS-RET extends lifespan in basal conditions. Here, we demonstrate that ROS-RET signalling requires increased electron entry and uninterrupted electron flow through the electron transport chain (ETC). We find that in old fruit flies, ROS-RET is abolished when electron flux is decreased and that their mitochondria produce consistently high levels of mtROS. Finally, we demonstrate that in young flies, limiting electron exit, but not entry, from the ETC phenocopies mtROS generation observed in old individuals. Our results elucidate the mechanism by which ROS signalling is lost during ageing.

Published

2023

22. Mitochondrial redox signaling: a key player in aging and disease

Author

Maria Vitale, Alberto Sanz, Filippo Scialò, Vitale, Maria, Sanz, Alberto, and Scialo, Filippo

Subjects

Aging, mtROS propagation, electron transport chain, mitochondrial reactive oxygen specie, Cell Biology, redox signaling, reverse electron transport

Published

2023

23. Methanogenesis: Syntrophic Metabolism

Author

Sieber, J. R., McInerney, M. J., Plugge, C. M., Schink, B., Gunsalus, R. P., and Timmis, Kenneth N., editor

Published

2010

24. Membrane potential and delta pH dependency of reverse electron transport-associated hydrogen peroxide production in brain and heart mitochondria.

Author

Komlódi, Tímea, Geibl, Fanni F., Sassani, Matilde, Ambrus, Attila, and Tretter, László

Subjects

*ELECTRON transport, *ISCHEMIA, *REACTIVE oxygen species, *MITOCHONDRIA, *FLUORESCENCE

Abstract

Succinate-driven reverse electron transport (RET) is one of the main sources of mitochondrial reactive oxygen species (mtROS) in ischemia-reperfusion injury. RET is dependent on mitochondrial membrane potential (Δψm) and transmembrane pH difference (ΔpH), components of the proton motive force (pmf); a decrease in Δψm and/or ΔpH inhibits RET. In this study we aimed to determine which component of the pmf displays the more dominant effect on RET-provoked ROS generation in isolated guinea pig brain and heart mitochondria respiring on succinate or α-glycerophosphate (α-GP). Δψm was detected via safranin fluorescence and a TPP+ electrode, the rate of H2O2 formation was measured by Amplex UltraRed, the intramitochondrial pH (pHin) was assessed via BCECF fluorescence. Ionophores were used to dissect the effects of the two components of pmf. The K+/H+ exchanger, nigericin lowered pHin and ΔpH, followed by a compensatory increase in Δψm that led to an augmented H2O2 production. Valinomycin, a K+ ionophore, at low [K+] increased ΔpH and pHin, decreased Δψm, which resulted in a decline in H2O2 formation. It was concluded that Δψm is dominant over ∆pH in modulating the succinate- and α-GP-evoked RET. The elevation of extramitochondrial pH was accompanied by an enhanced H2O2 release and a decreased ∆pH. This phenomenon reveals that from the pH component not ∆pH, but rather absolute value of pH has higher impact on the rate of mtROS formation. Minor decrease of Δψm might be applied as a therapeutic strategy to attenuate RET-driven ROS generation in ischemia-reperfusion injury. [ABSTRACT FROM AUTHOR]

Published

2018

25. Role of Mitochondrial Reverse Electron Transport in ROS Signaling: Potential Roles in Health and Disease

Author

Filippo Scialò, Daniel J. Fernández-Ayala, and Alberto Sanz

Subjects

mitochondria, reverse electron transport, ROS, complex I, redox signaling, Physiology, QP1-981

Abstract

Reactive Oxygen Species (ROS) can cause oxidative damage and have been proposed to be the main cause of aging and age-related diseases including cancer, diabetes and Parkinson's disease. Accordingly, mitochondria from old individuals have higher levels of ROS. However, ROS also participate in cellular signaling, are instrumental for several physiological processes and boosting ROS levels in model organisms extends lifespan. The current consensus is that low levels of ROS are beneficial, facilitating adaptation to stress via signaling, whereas high levels of ROS are deleterious because they trigger oxidative stress. Based on this model the amount of ROS should determine the physiological effect. However, recent data suggests that the site at which ROS are generated is also instrumental in determining effects on cellular homeostasis. The best example of site-specific ROS signaling is reverse electron transport (RET). RET is produced when electrons from ubiquinol are transferred back to respiratory complex I, reducing NAD+ to NADH. This process generates a significant amount of ROS. RET has been shown to be instrumental for the activation of macrophages in response to bacterial infection, re-organization of the electron transport chain in response to changes in energy supply and adaptation of the carotid body to changes in oxygen levels. In Drosophila melanogaster, stimulating RET extends lifespan. Here, we review what is known about RET, as an example of site-specific ROS signaling, and its implications for the field of redox biology.

Published

2017

26. Physiologic Implications of Reactive Oxygen Species Production by Mitochondrial Complex I Reverse Electron Transport

Author

John O. Onukwufor, Brandon J. Berry, and Andrew P. Wojtovich

Subjects

reactive oxygen species, mitochondrial complex I, reverse electron transport, superoxide, hydrogen peroxide, ischemia reperfusion injury, oxidative damage, Therapeutics. Pharmacology, RM1-950

Abstract

Mitochondrial reactive oxygen species (ROS) can be either detrimental or beneficial depending on the amount, duration, and location of their production. Mitochondrial complex I is a component of the electron transport chain and transfers electrons from NADH to ubiquinone. Complex I is also a source of ROS production. Under certain thermodynamic conditions, electron transfer can reverse direction and reduce oxygen at complex I to generate ROS. Conditions that favor this reverse electron transport (RET) include highly reduced ubiquinone pools, high mitochondrial membrane potential, and accumulated metabolic substrates. Historically, complex I RET was associated with pathological conditions, causing oxidative stress. However, recent evidence suggests that ROS generation by complex I RET contributes to signaling events in cells and organisms. Collectively, these studies demonstrate that the impact of complex I RET, either beneficial or detrimental, can be determined by the timing and quantity of ROS production. In this article we review the role of site-specific ROS production at complex I in the contexts of pathology and physiologic signaling.

Published

2019

27. Melatonin drives apoptosis in head and neck cancer by increasing mitochondrial ROS generated via reverse electron transport

Author

Javier Florido, Laura Martinez‐Ruiz, César Rodriguez‐Santana, Alba López‐Rodríguez, Agustín Hidalgo‐Gutiérrez, Cécile Cottet‐Rousselle, Frédéric Lamarche, Uwe Schlattner, Ana Guerra‐Librero, Paula Aranda‐Martínez, Darío Acuña‐Castroviejo, Luis C. López, and Germaine Escames

Subjects

reactive oxygen species, apoptosis, Apoptosis, melatonin, oxidative damage, reverse electron transport, mitochondria, Electron Transport, Mice, Endocrinology, head and neck cancer cells, Head and Neck Neoplasms, Animals, Humans, Reactive Oxygen Species, Melatonin

Abstract

The oncostatic effects of melatonin correlate with increased reactive oxygen species (ROS) levels, but how melatonin induces this ROS generation is unknown. In the present study, we aimed to elucidate the two seemingly opposing actions of melatonin regarding its relationship with free radicals. We analyzed the effects of melatonin on head and neck squamous cell carcinoma cell lines (Cal-27 and SCC-9), which were treated with 0.5 or 1 mM melatonin. We further examined the potential effects of melatonin to induce ROS and apoptosis in Cal-27 xenograft mice. Here we report that melatonin mediates apoptosis in head and neck cancer by driving mitochondrial reverse electron transport (RET) to induce ROS production. Melatonin-induced changes in tumoral metabolism led to increased mitochondrial activity, which, in turn, induced ROS-dependent mitochondrial uncoupling. Interestingly, mitochondrial complex inhibitors, including rotenone, abolished the ROS elevation indicating that melatonin increased ROS generation via RET. Melatonin also increased membrane potential and CoQ10 H2 /CoQ10 ratio to elevate mitochondrial ROS production, which are essential conditions for RET. We found that genetic manipulation of cancer cells with alternative oxidase, which transfers electrons from QH2 to oxygen, inhibited melatonin-induced ROS generation, and apoptosis. RET restored the melatonin-induced oncostatic effect, highlighting the importance of RET as the site of ROS production. These results illustrate that RET and ROS production are crucial factors in melatonin's effects in cancer cells and establish the dual effect of melatonin in protecting normal cells and inducing apoptosis in cancer cells.

Published

2022

28. Role of Mitochondrial Reverse Electron Transport in ROS Signaling: Potential Roles in Health and Disease.

Author

Scialò, Filippo, Fernández-Ayala, Daniel J., and Sanz, Alberto

Subjects

REACTIVE oxygen species, MITOCHONDRIA, HOMEOSTASIS, OXIDATIVE stress, OXIDATIVE phosphorylation

Abstract

Reactive Oxygen Species (ROS) can cause oxidative damage and have been proposed to be the main cause of aging and age-related diseases including cancer, diabetes and Parkinson's disease. Accordingly, mitochondria from old individuals have higher levels of ROS. However, ROS also participate in cellular signaling, are instrumental for several physiological processes and boosting ROS levels in model organisms extends lifespan. The current consensus is that low levels of ROS are beneficial, facilitating adaptation to stress via signaling, whereas high levels of ROS are deleterious because they trigger oxidative stress. Based on this model the amount of ROS should determine the physiological effect. However, recent data suggests that the site at which ROS are generated is also instrumental in determining effects on cellular homeostasis. The best example of site-specific ROS signaling is reverse electron transport (RET). RET is produced when electrons from ubiquinol are transferred back to respiratory complex I, reducing NAD+ to NADH. This process generates a significant amount of ROS. RET has been shown to be instrumental for the activation of macrophages in response to bacterial infection, re-organization of the electron transport chain in response to changes in energy supply and adaptation of the carotid body to changes in oxygen levels. In Drosophila melanogaster, stimulating RET extends lifespan. Here, we review what is known about RET, as an example of site-specific ROS signaling, and its implications for the field of redox biology. [ABSTRACT FROM AUTHOR]

Published

2017

29. Mitochondrial redox signaling: a key player in aging and disease.

Author

Vitale M, Sanz A, and Scialò F

Subjects

Reactive Oxygen Species, Oxidation-Reduction

Published

2023

30. Site IQ in mitochondrial complex I generates S1QEL-sensitive superoxide/hydrogen peroxide in both the reverse and forward reactions.

Author

Gibbs ET, Lerner CA, Watson MA, Wong HS, Gerencser AA, and Brand MD

Subjects

Rats, Animals, NAD metabolism, Mitochondria metabolism, Electron Transport, Electron Transport Complex I metabolism, Electron Transport Complex I pharmacology, Superoxides metabolism, Hydrogen Peroxide metabolism

Abstract

Superoxide/hydrogen peroxide production by site IQ in complex I of the electron transport chain is conventionally assayed during reverse electron transport (RET) from ubiquinol to NAD. However, S1QELs (specific suppressors of superoxide/hydrogen peroxide production by site IQ) have potent effects in cells and in vivo during presumed forward electron transport (FET). Therefore, we tested whether site IQ generates S1QEL-sensitive superoxide/hydrogen peroxide during FET (site IQf), or alternatively, whether RET and associated S1QEL-sensitive superoxide/hydrogen peroxide production (site IQr) occurs in cells under normal conditions. We introduce an assay to determine if electron flow through complex I is thermodynamically forward or reverse: on blocking electron flow through complex I, the endogenous matrix NAD pool will become more reduced if flow before the challenge was forward, but more oxidised if flow was reverse. Using this assay we show in the model system of isolated rat skeletal muscle mitochondria that superoxide/hydrogen peroxide production by site IQ can be equally great whether RET or FET is running. We show that sites IQr and IQf are equally sensitive to S1QELs, and to rotenone and piericidin A, inhibitors that block the Q-site of complex I. We exclude the possibility that some sub-fraction of the mitochondrial population running site IQr during FET is responsible for S1QEL-sensitive superoxide/hydrogen peroxide production by site IQ. Finally, we show that superoxide/hydrogen peroxide production by site IQ in cells occurs during FET, and is S1QEL-sensitive., (© 2023 The Author(s).)

Published

2023

31. Uncovering the source of mitochondrial superoxide in pro-inflammatory macrophages: Insights from immunometabolism.

Author

Casey, Alva M. and Murphy, Michael P.

Subjects

*SUPEROXIDES, *MACROPHAGES, *ELECTRON transport, *MITOCHONDRIA, *REACTIVE oxygen species

Abstract

Mitochondrial-derived reactive oxygen species are important as antimicrobial agents and redox signals in pro-inflammatory macrophages. Macrophages produce superoxide in response to the TLR4 ligand LPS. However, the mechanism of LPS-induced superoxide generation is not fully understood. Superoxide is produced at complex I and complex III of the electron transport chain. Production of superoxide at either of these sites is highly dependent on the metabolic state of the cell which is dramatically altered by TLR4-induced metabolic reprogramming. This review will outline how metabolism impacts superoxide production in LPS-activated macrophages downstream of TLR4 signalling and address outstanding questions in this field. • Macrophages produce LPS-induced mitochondrial-derived superoxide. • The mechanism of LPS-induced mitochondrial superoxide production is unclear. • A proposed mechanism is by reverse electron transport (RET) at complex I. • RET is influenced by the metabolic state and mitochondrial properties. • Mitochondrial metabolism and properties dynamically change upon LPS treatment. [ABSTRACT FROM AUTHOR]

Published

2022

32. Mitochondrial complex I derived ROS regulate stress adaptation in Drosophila melanogaster

Author

Alberto Sanz, Rhoda Stefanatos, Ashwin Sriram, L. Miguel Martins, Samantha H. Y. Loh, Filippo Scialò, Ruth V. Spriggs, Loh, Sam [0000-0001-5073-6065], Martins, Luis [0000-0002-3019-4809], Apollo - University of Cambridge Repository, Scialo, F., Sriram, A., Stefanatos, R., Spriggs, R. V., Loh, S. H. Y., Martins, L. M., and Sanz, A.

Subjects

0301 basic medicine, Alternative oxidase, Reverse electron transport, Clinical Biochemistry, Cellular homeostasis, Heat stre, Mitochondrion, Biochemistry, Heat stress, Electron Transport, 03 medical and health sciences, 0302 clinical medicine, Complex I, Animals, lcsh:QH301-705.5, chemistry.chemical_classification, Reactive oxygen species, lcsh:R5-920, Electron Transport Complex I, biology, Chemistry, AOX, Organic Chemistry, Hydrogen Peroxide, biology.organism_classification, Reverse electron flow, Cell biology, 030104 developmental biology, Drosophila melanogaster, lcsh:Biology (General), Catalase, biology.protein, Reactive oxygen specie, Ectopic expression, lcsh:Medicine (General), 030217 neurology & neurosurgery, Research Paper

Abstract

Reactive Oxygen Species (ROS) are essential cellular messengers required for cellular homeostasis and regulate the lifespan of several animal species. The main site of ROS production is the mitochondrion, and within it, respiratory complex I (CI) is the main ROS generator. ROS produced by CI trigger several physiological responses that are essential for the survival of neurons, cardiomyocytes and macrophages. Here, we show that CI produces ROS when electrons flow in either the forward (Forward Electron Transport, FET) or reverse direction (Reverse Electron Transport, RET). We demonstrate that ROS production via RET (ROS-RET) is activated under thermal stress conditions and that interruption of ROS-RET production, through ectopic expression of the alternative oxidase AOX, attenuates the activation of pro-survival pathways in response to stress. Accordingly, we find that both suppressing ROS-RET signalling or decreasing levels of mitochondrial H2O2 by overexpressing mitochondrial catalase (mtCAT), reduces survival dramatically in flies under stress. Our results uncover a specific ROS signalling pathway where hydrogen peroxide (H2O2) generated by CI via RET is required to activate adaptive mechanisms, maximising survival under stress conditions., Graphical abstract Image 1, Highlights • Heat stress induces ROS generation through the activation of Reverse electron transport (ROS-RET). • Suppressing ROS-RET attenuates the transcriptional stress response reducing survival under stress. • Mitochondrial catalase reduces survival under stress, identifying H2O2 as the main ROS signalling molecule.

Published

2020

33. Membrane potential and delta pH dependency of reverse electron transport-associated hydrogen peroxide production in brain and heart mitochondria

Author

Matilde Sassani, Laszlo Tretter, Attila Ambrus, Fanni F. Geibl, and Timea Komlódi

Subjects

0301 basic medicine, Reverse electron transport, Succinate, Nigericin, Physiology, Guinea Pigs, Ionophore, Mitochondrion, Article, Mitochondria, Heart, Electron Transport, 03 medical and health sciences, Valinomycin, chemistry.chemical_compound, 0302 clinical medicine, Alpha-glycerophosphate, Animals, Humans, Membrane potential, chemistry.chemical_classification, Membrane Potential, Mitochondrial, Reactive oxygen species, Chemiosmosis, Brain, Cell Biology, Hydrogen Peroxide, Reverse electron flow, Mitochondria, 030104 developmental biology, chemistry, Proton motive force, Biophysics, 030217 neurology & neurosurgery

Abstract

Succinate-driven reverse electron transport (RET) is one of the main sources of mitochondrial reactive oxygen species (mtROS) in ischemia-reperfusion injury. RET is dependent on mitochondrial membrane potential (Δψm) and transmembrane pH difference (ΔpH), components of the proton motive force (pmf); a decrease in Δψm and/or ΔpH inhibits RET. In this study we aimed to determine which component of the pmf displays the more dominant effect on RET-provoked ROS generation in isolated guinea pig brain and heart mitochondria respiring on succinate or α-glycerophosphate (α-GP). Δψm was detected via safranin fluorescence and a TPP+ electrode, the rate of H2O2 formation was measured by Amplex UltraRed, the intramitochondrial pH (pHin) was assessed via BCECF fluorescence. Ionophores were used to dissect the effects of the two components of pmf. The K+/H+ exchanger, nigericin lowered pHin and ΔpH, followed by a compensatory increase in Δψm that led to an augmented H2O2 production. Valinomycin, a K+ ionophore, at low [K+] increased ΔpH and pHin, decreased Δψm, which resulted in a decline in H2O2 formation. It was concluded that Δψm is dominant over ∆pH in modulating the succinate- and α-GP-evoked RET. The elevation of extramitochondrial pH was accompanied by an enhanced H2O2 release and a decreased ∆pH. This phenomenon reveals that from the pH component not ∆pH, but rather absolute value of pH has higher impact on the rate of mtROS formation. Minor decrease of Δψm might be applied as a therapeutic strategy to attenuate RET-driven ROS generation in ischemia-reperfusion injury.

Published

2018

34. Control of mitochondrial superoxide production by reverse electron transport at complex I

Author

Ellen L. Robb, Marten Szibor, Andrew R. Hall, Tracy A. Prime, Andrew M. James, Simon Eaton, Carlo Viscomi, and Michael P. Murphy

Subjects

0301 basic medicine, Male, Alternative oxidase, endocrine system, endocrine system diseases, Ubiquinone, Wistar, Oxidative phosphorylation, Mitochondrion, Bioenergetics, Inbred C57BL, reactive oxygen species (ROS), reverse electron transport, Biochemistry, Oxidative Phosphorylation, Electron Transport, 03 medical and health sciences, chemistry.chemical_compound, Mice, mitochondrial membrane potential, Superoxides, Animals, redox signaling, Molecular Biology, chemistry.chemical_classification, Reactive oxygen species, Electron Transport Complex I, Chemistry, Superoxide, complex I, Heart, Cell Biology, Hydrogen Peroxide, Reverse electron flow, Rats, mitochondria, 030104 developmental biology, Coenzyme Q – cytochrome c reductase, Biophysics, Female, superoxide, coenzyme Q, RET, respiration, Mice, Inbred C57BL, Mitochondria, Heart, Rats, Wistar, Signal Transduction

Abstract

The generation of mitochondrial superoxide (O2˙̄) by reverse electron transport (RET) at complex I causes oxidative damage in pathologies such as ischemia reperfusion injury, but also provides the precursor to H2O2 production in physiological mitochondrial redox signaling. Here, we quantified the factors that determine mitochondrial O2˙̄ production by RET in isolated heart mitochondria. Measuring mitochondrial H2O2 production at a range of proton-motive force (Δp) values and for several coenzyme Q (CoQ) and NADH pool redox states obtained with the uncoupler p-trifluoromethoxyphenylhydrazone, we show that O2˙̄ production by RET responds to changes in O2 concentration, the magnitude of Δp, and the redox states of the CoQ and NADH pools. Moreover, we determined how expressing the alternative oxidase from the tunicate Ciona intestinalis to oxidize the CoQ pool affected RET-mediated O2˙̄ production at complex I, underscoring the importance of the CoQ pool for mitochondrial O2˙̄ production by RET. An analysis of O2˙̄ production at complex I as a function of the thermodynamic forces driving RET at complex I revealed that many molecules that affect mitochondrial reactive oxygen species production do so by altering the overall thermodynamic driving forces of RET, rather than by directly acting on complex I. These findings clarify the factors controlling RET-mediated mitochondrial O2˙̄ production in both pathological and physiological conditions. We conclude that O2˙̄ production by RET is highly responsive to small changes in Δp and the CoQ redox state, indicating that complex I RET represents a major mode of mitochondrial redox signaling.

Published

2018

35. High Ca2+ load promotes Hydrogen peroxide generation via activation of α-glycerophosphate dehydrogenase in brain mitochondria

Author

Tretter, Laszlo and Adam-Vizi, Vera

Subjects

*BRAIN mitochondria, *ANALYSIS of hydrogen peroxide, *CALCIUM ions, *DEHYDROGENASES, *GUINEA pigs as laboratory animals, *ALAMETHICIN, *MYXOTHIAZOL, *REACTIVE oxygen species

Abstract

Abstract: H2O2 generation associated with α-glycerophosphate (α-GP) oxidation was addressed in guinea pig brain mitochondria challenged with high Ca2+ load (10μM). Exposure to 10μM Ca2+ induced an abrupt 2.5-fold increase in H2O2 release compared to that measured in the presence of a physiological cytosolic Ca2+ concentration (100nM) from mitochondria respiring on 5mM α-GP in the presence of ADP (2mM). The Ca2+-induced stimulation of H2O2 generation was reversible and unaltered by the uniporter blocker Ru 360, indicating that it did not require Ca2+ uptake into mitochondria. Enhanced H2O2 generation by Ca2+ was also observed in the absence of ADP when mitochondria exhibited permeability transition pore opening with a decrease in the NAD(P)H level, dissipation of membrane potential, and mitochondrial swelling. Furthermore, mitochondria treated with the pore-forming peptide alamethicin also responded with an elevated H2O2 generation to a challenge with 10μM Ca2+. Ca2+-induced promotion of H2O2 formation was further enhanced by the complex III inhibitor myxothiazol. With 20mM α-GP concentration, stimulation of H2O2 formation by Ca2+ was detected only in the presence, not in the absence, of ADP. It is concluded that α-glycerophosphate dehydrogenase, which is accessible to and could be activated by a rise in the level of cytosolic Ca2+, makes a major contribution to Ca2+-stimulated H2O2 generation. This work highlights a unique high-Ca2+-stimulated reactive oxygen species-forming mechanism in association with oxidation of α-GP, which is largely independent of the bioenergetic state and can proceed even in damaged, functionally incompetent mitochondria. [Copyright &y& Elsevier]

Published

2012

36. Redox-optimized ROS balance: A unifying hypothesis

Author

Aon, M.A., Cortassa, S., and O'Rourke, B.

Subjects

*MITOCHONDRIAL membranes, *PHOSPHORYLATION, *OXIDATIVE stress, *ELECTRON transport, *OXIDATION-reduction reaction, *REACTIVE oxygen species, *ANTIOXIDANTS, *CELLULAR signal transduction

Abstract

Abstract: While it is generally accepted that mitochondrial reactive oxygen species (ROS) balance depends on the both rate of single electron reduction of O2 to superoxide (O2 −) by the electron transport chain and the rate of scavenging by intracellular antioxidant pathways, considerable controversy exists regarding the conditions leading to oxidative stress in intact cells versus isolated mitochondria. Here, we postulate that mitochondria have been evolutionarily optimized to maximize energy output while keeping ROS overflow to a minimum by operating in an intermediate redox state. We show that at the extremes of reduction or oxidation of the redox couples involved in electron transport (NADH/NAD+) or ROS scavenging (NADPH/NADP+, GSH/GSSG), respectively, ROS balance is lost. This results in a net overflow of ROS that increases as one moves farther away from the optimal redox potential. At more reduced mitochondrial redox potentials, ROS production exceeds scavenging, while under more oxidizing conditions (e.g., at higher workloads) antioxidant defenses can be compromised and eventually overwhelmed. Experimental support for this hypothesis is provided in both cardiomyocytes and in isolated mitochondria from guinea pig hearts. The model reconciles, within a single framework, observations that isolated mitochondria tend to display increased oxidative stress at high reduction potentials (and high mitochondrial membrane potential, ∆Ψ m), whereas intact cardiac cells can display oxidative stress either when mitochondria become more uncoupled (i.e., low ∆Ψ m) or when mitochondria are maximally reduced (as in ischemia or hypoxia). The continuum described by the model has the potential to account for many disparate experimental observations and also provides a rationale for graded physiological ROS signaling at redox potentials near the minimum. [Copyright &y& Elsevier]

Published

2010

37. The production of reactive oxygen species by complex I.

Author

Hirst, Judy, King, Martin S., and Pryde, Kenneth R.

Subjects

*REACTIVE oxygen species, *OXIDATIVE stress, *NEUROMUSCULAR diseases, *ENZYMES, *FLAVINS, *OXIDATION, *MITOCHONDRIA

Abstract

ROS (reactive oxygen species) are considered to be a major cause of cellular oxidative stress, linked to neuromuscular diseases and aging. Complex I (NADH:ubiquinone oxidoreductase) is one of the main contributors to superoxide production by mitochondria, and knowledge of its mechanism of O2 reduction is required for the formulation of causative connections between complex I defects and pathological effects. There is evidence for two distinct (but not mutually exclusive) sites of O2 reduction by complex I. Studies of the isolated enzyme largely support the participation of the reduced flavin mononucleotide in the active site for NADH oxidation, and this mechanism is supported in mitochondria by correlations between the NAD(P)+ potential and O2 reduction. In addition, studies of intact mitochondria or submitochondrial particles have suggested a mechanism involving the quinone-binding site, supported by observations during reverse electron transport and the use of 'Q-site' inhibitors. Here, we discuss extant data and models for O2 reduction by complex I. We compare results from the isolated enzyme with results from intact mitochondria, aiming to identify similarities and differences between them and progress towards combining them to form a single, unified picture. [ABSTRACT FROM AUTHOR]

Published

2008

38. Superoxide and hydrogen peroxide production by Drosophila mitochondria

Author

Miwa, Satomi, St-Pierre, Julie, Partridge, Linda, and Brand, Martin D.

Subjects

*DROSOPHILA, *AGING, *FREE radicals, *HYDROGEN peroxide, *ANTIFUNGAL agents

Abstract

Drosophila melanogaster is a key model organism for genetic investigation of the role of free radicals in aging, but biochemical understanding is lacking. Superoxide production by Drosophila mitochondria was measured fluorometrically as hydrogen peroxide, using its dependence on substrates, inhibitors, and added superoxide dismutase to determine sites of production and their topology. Glycerol 3-phosphate dehydrogenase and center o of complex III in the presence of antimycin had the greatest maximum capacities to generate superoxide on the cytosolic side of the inner membrane. Complex I had significant capacity on the matrix side. Center i of complex III, cytochrome c, and complex IV produced no superoxide. Native superoxide generation by isolated mitochondria was also measured without added inhibitors. There was a high rate of superoxide production with sn-glycerol 3-phosphate as substrate; two-thirds mostly from glycerol 3-phosphate dehydrogenase on the cytosolic side and one-third on the matrix side from complex I following reverse electron transport. There was little superoxide production from any site with NADH-linked substrate. Superoxide production by complex I following reverse electron flow from glycerol 3-phosphate was particularly sensitive to membrane potential, decreasing 70% when potential decreased 10 mV, showing that mild uncoupling lowers superoxide production in the matrix very effectively. [Copyright &y& Elsevier]

Published

2003

39. Physiologic Implications of Reactive Oxygen Species Production by Mitochondrial Complex I Reverse Electron Transport

Author

Andrew P. Wojtovich, John O. Onukwufor, and Brandon J. Berry

Subjects

0301 basic medicine, Physiology, Clinical Biochemistry, chemistry.chemical_element, hydrogen peroxide, Review, oxidative damage, medicine.disease_cause, reverse electron transport, Biochemistry, Oxygen, 03 medical and health sciences, chemistry.chemical_compound, Electron transfer, 0302 clinical medicine, medicine, Molecular Biology, Membrane potential, chemistry.chemical_classification, reactive oxygen species, ischemia reperfusion injury, Reactive oxygen species, Superoxide, lcsh:RM1-950, Cell Biology, Electron transport chain, Reverse electron flow, Cell biology, 030104 developmental biology, lcsh:Therapeutics. Pharmacology, chemistry, superoxide, 030217 neurology & neurosurgery, Oxidative stress, mitochondrial complex I

Abstract

Mitochondrial reactive oxygen species (ROS) can be either detrimental or beneficial depending on the amount, duration, and location of their production. Mitochondrial complex I is a component of the electron transport chain and transfers electrons from NADH to ubiquinone. Complex I is also a source of ROS production. Under certain thermodynamic conditions, electron transfer can reverse direction and reduce oxygen at complex I to generate ROS. Conditions that favor this reverse electron transport (RET) include highly reduced ubiquinone pools, high mitochondrial membrane potential, and accumulated metabolic substrates. Historically, complex I RET was associated with pathological conditions, causing oxidative stress. However, recent evidence suggests that ROS generation by complex I RET contributes to signaling events in cells and organisms. Collectively, these studies demonstrate that the impact of complex I RET, either beneficial or detrimental, can be determined by the timing and quantity of ROS production. In this article we review the role of site-specific ROS production at complex I in the contexts of pathology and physiologic signaling.

Published

2019

40. Substrate-dependent differential regulation of mitochondrial bioenergetics in the heart and kidney cortex and outer medulla.

Author

Tomar, Namrata, Zhang, Xiao, Kandel, Sunil M., Sadri, Shima, Yang, Chun, Liang, Mingyu, Audi, Said H., Cowley, Allen W., and Dash, Ranjan K.

Subjects

*KIDNEY cortex, *BIOENERGETICS, *HEART, *MITOCHONDRIA, *ELECTRON transport, *MEMBRANE potential

Abstract

The kinetics and efficiency of mitochondrial oxidative phosphorylation (OxPhos) can depend on the choice of respiratory substrates. Furthermore, potential differences in this substrate dependency among different tissues are not well-understood. Here, we determined the effects of different substrates on the kinetics and efficiency of OxPhos in isolated mitochondria from the heart and kidney cortex and outer medulla (OM) of Sprague-Dawley rats. The substrates were pyruvate+malate, glutamate+malate, palmitoyl-carnitine+malate, alpha-ketoglutarate+malate, and succinate±rotenone at saturating concentrations. The kinetics of OxPhos were interrogated by measuring mitochondrial bioenergetics under different ADP perturbations. Results show that the kinetics and efficiency of OxPhos are highly dependent on the substrates used, and this dependency is distinctly different between heart and kidney. Heart mitochondria showed higher respiratory rates and OxPhos efficiencies for all substrates in comparison to kidney mitochondria. Cortex mitochondria respiratory rates were higher than OM mitochondria, but OM mitochondria OxPhos efficiencies were higher than cortex mitochondria. State 3 respiration was low in heart mitochondria with succinate but increased significantly in the presence of rotenone, unlike kidney mitochondria. Similar differences were observed in mitochondrial membrane potential. Differences in H 2 O 2 emission in the presence of succinate±rotenone were observed in heart mitochondria and to a lesser extent in OM mitochondria, but not in cortex mitochondria. Bioenergetics and H 2 O 2 emission data with succinate±rotenone indicate that oxaloacetate accumulation and reverse electron transfer may play a more prominent regulatory role in heart mitochondria than kidney mitochondria. These studies provide novel quantitative data demonstrating that the choice of respiratory substrates affects mitochondrial responses in a tissue-specific manner. • We investigated OxPhos kinetics in the heart and kidney cortex and OM under different substrates. • Heart showed higher mitochondrial OxPhos efficiency for all substrates in comparison to kidney. • Respiration of cortex mitochondria was higher than OM mitochondria. • OxPhos efficiency of OM mitochondria was higher than cortex mitochondria. • Reverse electron transport was prominent in heart mitochondria compared to kidney mitochondria. [ABSTRACT FROM AUTHOR]

Published

2022

41. Regulation of reverse electron transfer at mitochondrial complex I by unconventional Notch action in cancer stem cells.

Author

Ojha, Rani, Tantray, Ishaq, Rimal, Suman, Mitra, Siddhartha, Cheshier, Sam, and Lu, Bingwei

Subjects

*CANCER stem cells, *CHARGE exchange, *NAD (Coenzyme), *NEURAL stem cells, *MITOCHONDRIA, *BRAIN tumors

Abstract

Metabolic flexibility is a hallmark of many cancers where mitochondrial respiration is critically involved, but the molecular underpinning of mitochondrial control of cancer metabolic reprogramming is poorly understood. Here, we show that reverse electron transfer (RET) through respiratory chain complex I (RC-I) is particularly active in brain cancer stem cells (CSCs). Although RET generates ROS, NAD+/NADH ratio turns out to be key in mediating RET effect on CSC proliferation, in part through the NAD+-dependent Sirtuin. Mechanistically, Notch acts in an unconventional manner to regulate RET by interacting with specific RC-I proteins containing electron-transporting Fe–S clusters and NAD(H)-binding sites. Genetic and pharmacological interference of Notch-mediated RET inhibited CSC growth in Drosophila brain tumor and mouse glioblastoma multiforme (GBM) models. Our results identify Notch as a regulator of RET and RET-induced NAD+/NADH balance, a critical mechanism of metabolic reprogramming and a metabolic vulnerability of cancer that may be exploited for therapeutic purposes. • Cancer cells undergo active RET along C-I • NAD+/NADH ratio change critically mediates RET effect on cancer cell behavior • Notch acts unconventionally to promote RET by interacting with C-I proteins • Pharmacological inhibition of RET retards brain tumor growth in flies and mice Metabolic reprogramming is a hallmark of cancer. The role of mitochondria in this process remains enigmatic. Ojha et al. show that cancer cells undergo active reverse electron transfer (RET) and that Notch acts in an unconventional manner to regulate RET. Pharmacological inhibition of RET is beneficial in brain tumor models. [ABSTRACT FROM AUTHOR]

Published

2022

42. A microbiologist's odyssey: Bacterial viruses to photosynthetic bacteria.

Author

Gest, Howard

Abstract

Perspective can be defined as the relationships or relative importance of facts or matters from any special point of view. Thus, my Personal perspective reflects the threads I followed in a 50-year journey of research in the complex tapestry of bioenergetics and various aspects of microbial metabolism. An early interest in biochemical and microbial evolution led to the fertile hunting grounds of anoxygenic photosynthetic bacteria. Viewed as a physiological class, these organisms show remarkable metabolic versatility in that certain individual species are capable of using all the known major types of energy conversion (photosynthetic, respiratory, and fermentative) to support growth. Since such anoxyphototrophs are readily amenable to molecular genetic/biological manipulation, it can be expected that they will eventually provide important clues for unraveling the evolutionary relationships of the several kinds of energy conversion. I gradually came to believe that understanding the evolution of phototrophs would require detailed knowledge not only of how light is converted to chemical energy, but also of a) pathways of monomer production from extracellular sources of carbon and nitrogen and b) mechanisms cells use for integrating ATP regeneration with the energy-requiring biosyntheses of biological macromolecules. Serendipic observation of photoproduction of H from organic compounds by Rhodospirillum rubrum in 1949 led to discovery of N fixation by anoxyphototrophs, and this capacity was later exploited for the isolation of hitherto unknown species of photosynthetic prokaryotes, including the heliobacteria. Recent studies on the reaction centers of the heliobacteria suggest the possibility that these bacteria are descendents of early phototrophs that gave rise to oxygenic photosynthetic organisms. [ABSTRACT FROM AUTHOR]

Published

1994

43. Reduced pyridine nucleotides in Pseudomonas carboxydovorans are formed by reverse electron transfer linked to proton motive force.

Author

Jacobitz, Susanne and Meyer, Ortwin

Abstract

In cell suspensions of Pseudomonas carboxydovorans pulsed with lithotrophic substrates (CO or H) in the presence of oxygen, formation of reduced pyridine nucleotides and of ATP could be demonstrated using the bioluminescent assay. Experiments employing base-acid transition, an uncoupler and inhibitors of ATPase or electron transport enabled us to propose a model for the formation of NAD(P)H in chemolithotrophically growing P. carboxydovorans. The protonophor FCCP (carbonly-p-trifluormethoxyphenylhydrazon) inhibited both, formation of NAD(P)H and of ATP. In the absence of oxygen, a chemical potential imposed by base-acid transition resulted in the formation of NAD(P)H and ATP when electrogenic substrates (CO or H) were present. This suggests proton motive force-driven NAD(P)H formation. The proton motive force was generated by oxidation of substrate, and not by ATP hydrolysis, as obvious from NAD(P)H formation during inhibition of ATP synthesis by oligomycin and N,N′-dicyclohexylcarbodiimide. That the CO-born electrons are transferred via the ubiquinone 10-cytochrome b region to NADH dehydrogenase functioning in the reverse direction, was indicated by inhibition of NAD(P)H formation by HQNO (2-n-heptyl-4-hydroxyquinoline-N-oxide) and rotenone, and by resistance to antimycin A. We conclude that in P. carboxydovorans, growing with CO or H, electrons and a proton motive force, generated by respiration, are required to drive an reverse electron transfer for the formation of reduced pyridine nucleotides. [ABSTRACT FROM AUTHOR]

Published

1986

44. Energy conservation and pyridine nucleotide reduction in chemoautotrophic bacteria: a thermodynamic analysis.

Author

Wheelis, Mark

Abstract

Respiratory and reverse electron transport by chemoautotrophic bacteria have been formulated in chemiosmotic terms. A thermodynamic analysis of this model, assuming equilibrium conditions, indicates that respiration by most chemoautotrophs can generate a protonmotive force easily sufficient to drive both ATP synthesis and reverse electron transport. [ABSTRACT FROM AUTHOR]

Published

1984

45. Recollections.

Author

Frenkel, Albert

Abstract

About 1939, Sam Ruben and Martin Kamen introduced me to the emergent application of artificial radio-isotopes in the study of photosynthesis. While my own experiments on CO fixation by isolated chloroplasts turned out to be negative, their laboratory provided me with an informative and exciting experience. Also, there were many stimulating contacts with Cornelis van Niel, Robert Emerson, Don DeVault and many other outstanding scientists. Efforts on my part to obtain a better understanding of intermediary metabolism, eventually led me to Fritz Lipmann's laboratory. There I was encouraged to study the metabolic activities of cell-free preparations of photosynthetic purple bacteria. Investigations of oxidative phosphorylation by isolated bacterial chromatophores in the dark raised questions about the possible effects of light on the phosphorylation activities of such preparations. Surprisingly, high rates of phosphorylation were observed in the light in the absence of molecular oxygen ('light-induced phosphorylation'). In this process, adenosine diphosphate (ADP) and inorganic phosphate (P) could be converted quantitatively into adenosine triphosphate (ATP). It was postulated that this process was 'cyclic' in nature, as only catalytic concentrations of added electron donors were required. Later, at Minnesota, it could be shown that similar chromatophore preparations, in the presence of suitable electron donors, could reduce nicotinamide-adenine dinucleotide (NAD) to NADH in the light. It was then demonstrated that the chromatophores of Rhodospirilum rubrum, as well as the smaller membrane components derived from them, must contain the active metabolic components for these photosynthetic reactions. These observations, and studies on the kinetics of the formation and decay of light-induced free radicals, appeared to demonstrate the usefulness of bacterial chromatophores and of their membrane fragments in the study of partial reactions of bacterial photosynthesis. Since that time, numerous investigators elsewhere have carried out remarkable research on the purification and eventual crystallization of distinct bacterial membrane components, capable of carrying out well characterized photochemical and electron transport reactions. [ABSTRACT FROM AUTHOR]

Published

1993

46. Control of mitochondrial superoxide production by reverse electron transport at complex I

Author

Robb, Ellen L, Hall, Andrew R, Prime, Tracy A, Eaton, Simon, Szibor, Marten, Viscomi, Carlo, James, Andrew M, Murphy, Michael P, Murphy, Michael P [0000-0003-1115-9618], and Apollo - University of Cambridge Repository

Subjects

Male, endocrine system, endocrine system diseases, Ubiquinone, reactive oxygen species (ROS), reverse electron transport, Mitochondria, Heart, Oxidative Phosphorylation, Electron Transport, Mice, mitochondrial membrane potential, Superoxides, Animals, Rats, Wistar, redox signaling, Electron Transport Complex I, complex I, Hydrogen Peroxide, Rats, mitochondria, Mice, Inbred C57BL, Female, superoxide, coenzyme Q, RET, respiration, Signal Transduction

Abstract

The generation of mitochondrial superoxide (O2̇̄) by reverse electron transport (RET) at complex I causes oxidative damage in pathologies such as ischemia reperfusion injury, but also provides the precursor to H2O2 production in physiological mitochondrial redox signaling. Here, we quantified the factors that determine mitochondrial O2̇̄ production by RET in isolated heart mitochondria. Measuring mitochondrial H2O2 production at a range of proton-motive force (Δp) values and for several coenzyme Q (CoQ) and NADH pool redox states obtained with the uncoupler p-trifluoromethoxyphenylhydrazone, we show that O2̇̄ production by RET responds to changes in O2 concentration, the magnitude of Δp, and the redox states of the CoQ and NADH pools. Moreover, we determined how expressing the alternative oxidase from the tunicate Ciona intestinalis to oxidize the CoQ pool affected RET-mediated O2̇̄ production at complex I, underscoring the importance of the CoQ pool for mitochondrial O2̇̄ production by RET. An analysis of O2̇̄ production at complex I as a function of the thermodynamic forces driving RET at complex I revealed that many molecules that affect mitochondrial reactive oxygen species production do so by altering the overall thermodynamic driving forces of RET, rather than by directly acting on complex I. These findings clarify the factors controlling RET-mediated mitochondrial O2̇̄ production in both pathological and physiological conditions. We conclude that O2̇̄ production by RET is highly responsive to small changes in Δp and the CoQ redox state, indicating that complex I RET represents a major mode of mitochondrial redox signaling.

Published

2018

47. Comparative proteome analysis of propionate degradation by Syntrophobacter fumaroxidans in pure culture and in coculture with methanogens

Author

Sedano‐Núñez, Vicente T., Boeren, Sjef, Stams, Alfons J. M., Plugge, Caroline M., and Universidade do Minho

Subjects

Deltaproteobacteria, propionate oxidation, Formates, Proteome, Syntrophy, Biochemie, reverse electron transport, Biochemistry, Microbiology, Electron Transport, hydrogenases, Methanospirillum, Hydrogenase, Microbiologie, Life Science, Research Articles, WIMEK, Science & Technology, Sulfates, Methanobacterium, Coculture Techniques, interspecies electron transfer, sulfate-reducing bacteria, Desulfovibrio, Propionates, Oxidation-Reduction, formate dehydrogenases, Research Article, Hydrogen

Abstract

Syntrophobacter fumaroxidans is a sulfatereducing bacterium able to grow on propionate axenically or in syntrophic interaction with methanogens or other sulfatereducing bacteria. We performed a proteome analysis of S. fumaroxidans growing with propionate axenically with sulfate or fumarate, and in syntrophy with Methanospirillum hungatei, Methanobacterium formicicum or Desulfovibrio desulfuricans. Special attention was put on the role of hydrogen and formate in interspecies electron transfer (IET) and energy conservation. Formate dehydrogenase Fdh1 and hydrogenase Hox were the main confurcating enzymes used for energy conservation. In the periplasm, Fdh2 and hydrogenase Hyn play an important role in reverse electron transport associated with succinate oxidation. Periplasmic Fdh3 and Fdh5 were involved in IET. The sulfate reduction pathway was poorly regulated and many enzymes associated with sulfate reduction (Sat, HppA, AprAB, DsrAB and DsrC) were abundant even at conditions where sulfate was not present. Proteins similar to heterodisulfide reductases (Hdr) were abundant. Hdr/Flox was detected in all conditions while HdrABC/HdrL was exclusively detected when sulfate was available; these complexes most likely confurcate electrons. Our results suggest that S. fumaroxidans mainly used formate for electron release and that different confurcating mechanisms were used in its sulfidogenic metabolism. This article is protected by copyright, This research was supported by the Dutch Technology Foundation (STW) (project 11603), which is part of the Netherlands Organization for Scientific Research (NWO), and which is partly funded by the Ministry of Economic Affairs. Research of AJMS is supported by the European Research Council (ERC grant 323009) and the Gravitation grant (024.002.002) of the Netherlands Ministry of Education, Cultureand Science., info:eu-repo/semantics/publishedVersion

Published

2018

48. Tissue- and substrate-dependent mitochondrial responses to acute hypoxia-reoxygenation stress in a marine bivalve (Crassostrea gigas).

Author

Adzigbli L, Sokolov EP, Ponsuksili S, and Sokolova IM

Subjects

Animals, Hydrogen Peroxide metabolism, Hypoxia metabolism, Mitochondria metabolism, Reactive Oxygen Species metabolism, Crassostrea metabolism

Abstract

Hypoxia is a major stressor for aquatic organisms, yet intertidal organisms such as the oyster Crassostrea gigas are adapted to frequent oxygen fluctuations by metabolically adjusting to shifts in oxygen and substrate availability during hypoxia-reoxygenation (H/R). We investigated the effects of acute H/R stress (15 min at ∼0% O2 and 10 min reoxygenation) on isolated mitochondria from the gill and the digestive gland of C. gigas respiring on different substrates (pyruvate, glutamate, succinate, palmitate and their mixtures). Gill mitochondria showed better capacity for amino acid and fatty acid oxidation compared with mitochondria from the digestive gland. Mitochondrial responses to H/R stress strongly depended on the substrate and the activity state of mitochondria. In mitochondria oxidizing NADH-linked substrates, exposure to H/R stress suppressed oxygen consumption and generation of reactive oxygen species (ROS) in the resting state, whereas in the ADP-stimulated state, ROS production increased despite little change in respiration. As a result, electron leak (measured as H2O2 to O2 ratio) increased after H/R stress in the ADP-stimulated mitochondria with NADH-linked substrates. In contrast, H/R exposure stimulated succinate-driven respiration without an increase in electron leak. Reverse electron transport (RET) did not significantly contribute to succinate-driven ROS production in oyster mitochondria except for a slight increase in the OXPHOS state during post-hypoxic recovery. A decrease in NADH-driven respiration and ROS production, enhanced capacity for succinate oxidation and resistance to RET might assist in post-hypoxic recovery of oysters mitigating oxidative stress and supporting rapid ATP re-synthesis during oxygen fluctuations, as is commonly observed in estuaries and intertidal zones., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2022. Published by The Company of Biologists Ltd.)

Published

2022

49. Being right on Q: shaping eukaryotic evolution

Author

Dave Speijer

Subjects

uncoupling, 0301 basic medicine, Mitochondrial ROS, Respiratory chain, Review Article, Mitochondrion, Biology, reverse electron transport, Biochemistry, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Carnitine, Review Articles, Molecular Biology, Beta oxidation, reactive oxygen species, chemistry.chemical_classification, Reactive oxygen species, Electron Transport Complex I, FADH2/NADH ratio, peroxisomes, Eukaryota, Fatty acid, Cell Biology, Peroxisome, Biological Evolution, Mitochondria, Cell biology, 030104 developmental biology, chemistry, 030217 neurology & neurosurgery, medicine.drug

Abstract

Reactive oxygen species (ROS) formation by mitochondria is an incompletely understood eukaryotic process. I proposed a kinetic model [BioEssays (2011) 33, 88–94] in which the ratio between electrons entering the respiratory chain via FADH2 or NADH (the F/N ratio) is a crucial determinant of ROS formation. During glucose breakdown, the ratio is low, while during fatty acid breakdown, the ratio is high (the longer the fatty acid, the higher is the ratio), leading to higher ROS levels. Thus, breakdown of (very-long-chain) fatty acids should occur without generating extra FADH2 in mitochondria. This explains peroxisome evolution. A potential ROS increase could also explain the absence of fatty acid oxidation in long-lived cells (neurons) as well as other eukaryotic adaptations, such as dynamic supercomplex formation. Effective combinations of metabolic pathways from the host and the endosymbiont (mitochondrion) allowed larger varieties of substrates (with different F/N ratios) to be oxidized, but high F/N ratios increase ROS formation. This might have led to carnitine shuttles, uncoupling proteins, and multiple antioxidant mechanisms, especially linked to fatty acid oxidation [BioEssays (2014) 36, 634–643]. Recent data regarding peroxisome evolution and their relationships with mitochondria, ROS formation by Complex I during ischaemia/reperfusion injury, and supercomplex formation adjustment to F/N ratios strongly support the model. I will further discuss the model in the light of experimental findings regarding mitochondrial ROS formation.

Published

2016

50. Succinate Dehydrogenase Supports Metabolic Repurposing of Mitochondria to Drive Inflammatory Macrophages

Author

Mills, Evanna L, Kelly, Beth, Logan, Angela, Costa, Ana SH, Varma, Mukund, Bryant, Clare E, Tourlomousis, Panagiotis, Däbritz, J Henry M, Gottlieb, Eyal, Latorre, Isabel, Corr, Sinéad C, McManus, Gavin, Ryan, Dylan, Jacobs, Howard T, Szibor, Marten, Xavier, Ramnik J, Braun, Thomas, Frezza, Christian, Murphy, Michael P, O'Neill, Luke A, Bryant, Clare [0000-0002-2924-0038], Tourlomousis, Panagiotis [0000-0002-6152-8066], Frezza, Christian [0000-0002-3293-7397], Murphy, Mike [0000-0003-1115-9618], and Apollo - University of Cambridge Repository

Subjects

Lipopolysaccharides, Carbonyl Cyanide m-Chlorophenyl Hydrazone, immunometabolism, Citric Acid Cycle, Succinic Acid, macrophage, reverse electron transport, Oxidative Phosphorylation, Mitochondrial Proteins, Mice, Adenosine Triphosphate, Animals, innate immunity, Plant Proteins, Inflammation, Membrane Potential, Mitochondrial, Sequence Analysis, RNA, Macrophages, Macrophage Activation, succinate, succinate dehydrogenase, Hypoxia-Inducible Factor 1, alpha Subunit, Malonates, Interleukin-10, Mitochondria, Mice, Inbred C57BL, toll-like receptors, Oxidoreductases, Reactive Oxygen Species, Transcriptome, Glycolysis, Oxidation-Reduction

Abstract

Activated macrophages undergo metabolic reprogramming, which drives their pro-inflammatory phenotype, but the mechanistic basis for this remains obscure. Here, we demonstrate that upon lipopolysaccharide (LPS) stimulation, macrophages shift from producing ATP by oxidative phosphorylation to glycolysis while also increasing succinate levels. We show that increased mitochondrial oxidation of succinate via succinate dehydrogenase (SDH) and an elevation of mitochondrial membrane potential combine to drive mitochondrial reactive oxygen species (ROS) production. RNA sequencing reveals that this combination induces a pro-inflammatory gene expression profile, while an inhibitor of succinate oxidation, dimethyl malonate (DMM), promotes an anti-inflammatory outcome. Blocking ROS production with rotenone by uncoupling mitochondria or by expressing the alternative oxidase (AOX) inhibits this inflammatory phenotype, with AOX protecting mice from LPS lethality. The metabolic alterations that occur upon activation of macrophages therefore repurpose mitochondria from ATP synthesis to ROS production in order to promote a pro-inflammatory state.

Published

2017