Your search keyword '"Orr, Adam L"' showing total 12 results

1. Systems-level analyses dissociate genetic regulators of reactive oxygen species and energy production.

Author

Bennett NK, Lee M, Orr AL, and Nakamura K

Subjects

Reactive Oxygen Species metabolism, Mitochondrial Proteins metabolism, Adenosine Triphosphate metabolism, Oxidative Stress, Mitochondria metabolism, Mitochondrial Membranes metabolism

Abstract

Respiratory chain dysfunction can decrease ATP and increase reactive oxygen species (ROS) levels. Despite the importance of these metabolic parameters to a wide range of cellular functions and disease, we lack an integrated understanding of how they are differentially regulated. To address this question, we adapted a CRISPRi- and FACS-based platform to compare the effects of respiratory gene knockdown on ROS to their effects on ATP. Focusing on genes whose knockdown is known to decrease mitochondria-derived ATP, we showed that knockdown of genes in specific respiratory chain complexes (I, III, and CoQ10 biosynthesis) increased ROS, whereas knockdown of other low ATP hits either had no impact (mitochondrial ribosomal proteins) or actually decreased ROS (complex IV). Moreover, although shifting metabolic conditions profoundly altered mitochondria-derived ATP levels, it had little impact on mitochondrial or cytosolic ROS. In addition, knockdown of a subset of complex I subunits-including NDUFA8 , NDUFB4 , and NDUFS 8-decreased complex I activity, mitochondria-derived ATP, and supercomplex level, but knockdown of these genes had differential effects on ROS. Conversely, we found an essential role for ether lipids in the dynamic regulation of mitochondrial ROS levels independent of ATP. Thus, our results identify specific metabolic regulators of cellular ATP and ROS balance that may help dissect the roles of these processes in disease and identify therapeutic strategies to independently target energy failure and oxidative stress., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

2. Neuronal Apolipoprotein E4 Expression Results in Proteome-Wide Alterations and Compromises Bioenergetic Capacity by Disrupting Mitochondrial Function.

Author

Orr AL, Kim C, Jimenez-Morales D, Newton BW, Johnson JR, Krogan NJ, Swaney DL, and Mahley RW

Subjects

Adenosine Triphosphate metabolism, Animals, Cell Line, Tumor, Energy Metabolism, Mice, NAD metabolism, Reactive Oxygen Species metabolism, Stress, Physiological, Transcriptome, Apolipoprotein E4 metabolism, Mitochondria metabolism, Neurons metabolism, Proteome metabolism

Abstract

Apolipoprotein (apo) E4, the major genetic risk factor for Alzheimer's disease (AD), alters mitochondrial function and metabolism early in AD pathogenesis. When injured or stressed, neurons increase apoE synthesis. Because of its structural difference from apoE3, apoE4 undergoes neuron-specific proteolysis, generating fragments that enter the cytosol, interact with mitochondria, and cause neurotoxicity. However, apoE4's effect on mitochondrial respiration and metabolism is not understood in detail. Here we used biochemical assays and proteomic profiling to more completely characterize the effects of apoE4 on mitochondrial function and cellular metabolism in Neuro-2a neuronal cells stably expressing apoE4 or apoE3. Under basal conditions, apoE4 impaired respiration and increased glycolysis, but when challenged or stressed, apoE4-expressing neurons had 50% less reserve capacity to generate ATP to meet energy requirements than apoE3-expressing neurons. ApoE4 expression also decreased the NAD+/NADH ratio and increased the levels of reactive oxygen species and mitochondrial calcium. Global proteomic profiling revealed widespread changes in mitochondrial processes in apoE4 cells, including reduced levels of numerous respiratory complex subunits and major disruptions to all detected subunits in complex V (ATP synthase). Also altered in apoE4 cells were levels of proteins related to mitochondrial endoplasmic reticulum-associated membranes, mitochondrial fusion/fission, mitochondrial protein translocation, proteases, and mitochondrial ribosomal proteins. ApoE4-induced bioenergetic deficits led to extensive metabolic rewiring, but despite numerous cellular adaptations, apoE4-expressing neurons remained vulnerable to metabolic stress. Our results provide insights into potential molecular targets of therapies to correct apoE4-associated mitochondrial dysfunction and altered cellular metabolism.

Published

2019

3. Loss of α-Synuclein Does Not Affect Mitochondrial Bioenergetics in Rodent Neurons.

Author

Pathak D, Berthet A, Bendor JT, Yu K, Sellnow RC, Orr AL, Nguyen MK, Edwards RH, Manfredsson FP, and Nakamura K

Subjects

Animals, Dopamine metabolism, Hippocampus metabolism, Mice, Knockout, Parkinson Disease metabolism, alpha-Synuclein deficiency, alpha-Synuclein genetics, Mitochondria metabolism, Neurons metabolism, Synapses metabolism, alpha-Synuclein metabolism

Abstract

Increased α-synuclein (αsyn) and mitochondrial dysfunction play central roles in the pathogenesis of Parkinson's disease (PD), and lowering αsyn is under intensive investigation as a therapeutic strategy for PD. Increased αsyn levels disrupt mitochondria and impair respiration, while reduced αsyn protects against mitochondrial toxins, suggesting that interactions between αsyn and mitochondria influences the pathologic and physiologic functions of αsyn. However, we do not know if αsyn affects normal mitochondrial function or if lowering αsyn levels impacts bioenergetic function, especially at the nerve terminal where αsyn is enriched. To determine if αsyn is required for normal mitochondrial function in neurons, we comprehensively evaluated how lowering αsyn affects mitochondrial function. We found that αsyn knockout (KO) does not affect the respiration of cultured hippocampal neurons or cortical and dopaminergic synaptosomes, and that neither loss of αsyn nor all three (α, β and γ) syn isoforms decreased mitochondria-derived ATP levels at the synapse. Similarly, neither αsyn KO nor knockdown altered the capacity of synaptic mitochondria to meet the energy requirements of synaptic vesicle cycling or influenced the localization of mitochondria to dopamine (DA) synapses in vivo . Finally, αsyn KO did not affect overall energy metabolism in mice assessed with a Comprehensive Lab Animal Monitoring System. These studies suggest either that αsyn has little or no significant physiological effect on mitochondrial bioenergetic function, or that any such functions are fully compensated for when lost. These results implicate that αsyn levels can be reduced in neurons without impairing (or improving) mitochondrial bioenergetics or distribution., Competing Interests: Authors report no conflict of interest.

Published

2017

4. Suppressors of superoxide production from mitochondrial complex III.

Author

Orr AL, Vargas L, Turk CN, Baaten JE, Matzen JT, Dardov VJ, Attle SJ, Li J, Quackenbush DC, Goncalves RL, Perevoshchikova IV, Petrassi HM, Meeusen SL, Ainscow EK, and Brand MD

Subjects

Adenosine Triphosphate biosynthesis, Animals, Antimycin A analogs & derivatives, Antimycin A antagonists & inhibitors, Antimycin A pharmacology, Dose-Response Relationship, Drug, Female, HEK293 Cells, High-Throughput Screening Assays, Humans, Hydrogen Peroxide antagonists & inhibitors, Hydrogen Peroxide metabolism, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells metabolism, Male, Mitochondria metabolism, Oxidative Phosphorylation drug effects, Oxidative Stress, Rats, Rats, Sprague-Dawley, Rats, Wistar, Signal Transduction, Superoxides metabolism, Electron Transport Complex III metabolism, Free Radical Scavengers pharmacology, Mitochondria drug effects, Pyrazoles pharmacology, Pyrimidines pharmacology, Superoxides antagonists & inhibitors

Abstract

Mitochondrial electron transport drives ATP synthesis but also generates reactive oxygen species, which are both cellular signals and damaging oxidants. Superoxide production by respiratory complex III is implicated in diverse signaling events and pathologies, but its role remains controversial. Using high-throughput screening, we identified compounds that selectively eliminate superoxide production by complex III without altering oxidative phosphorylation; they modulate retrograde signaling including cellular responses to hypoxic and oxidative stress.

Published

2015

5. A refined analysis of superoxide production by mitochondrial sn-glycerol 3-phosphate dehydrogenase.

Author

Orr AL, Quinlan CL, Perevoshchikova IV, and Brand MD

Subjects

Animals, Cytochrome b Group metabolism, Electron Transport Chain Complex Proteins antagonists & inhibitors, Electron Transport Chain Complex Proteins metabolism, Female, Glycerophosphates metabolism, Hydrogen Peroxide metabolism, Mitochondrial Membranes metabolism, Organ Specificity, Oxidation-Reduction, Rats, Rats, Wistar, Glycerolphosphate Dehydrogenase metabolism, Mitochondria enzymology, Superoxides metabolism

Abstract

The oxidation of sn-glycerol 3-phosphate by mitochondrial sn-glycerol 3-phosphate dehydrogenase (mGPDH) is a major pathway for transfer of cytosolic reducing equivalents to the mitochondrial electron transport chain. It is known to generate H(2)O(2) at a range of rates and from multiple sites within the chain. The rates and sites depend upon tissue source, concentrations of glycerol 3-phosphate and calcium, and the presence of different electron transport chain inhibitors. We report a detailed examination of H(2)O(2) production during glycerol 3-phosphate oxidation by skeletal muscle, brown fat, brain, and heart mitochondria with an emphasis on conditions under which mGPDH itself is the source of superoxide and H(2)O(2). Importantly, we demonstrate that a substantial portion of H(2)O(2) production commonly attributed to mGPDH originates instead from electron flow through the ubiquinone pool into complex II. When complex II is inhibited and mGPDH is the sole superoxide producer, the rate of superoxide production depends on the concentrations of glycerol 3-phosphate and calcium and correlates positively with the predicted reduction state of the ubiquinone pool. mGPDH-specific superoxide production plateaus at a rate comparable with the other major sites of superoxide production in mitochondria, the superoxide-producing center shows no sign of being overreducible, and the maximum superoxide production rate correlates with mGPDH activity in four different tissues. mGPDH produces superoxide approximately equally toward each side of the mitochondrial inner membrane, suggesting that the Q-binding pocket of mGPDH is the major site of superoxide generation. These results clarify the maximum rate and mechanism of superoxide production by mGPDH.

Published

2012

6. Mitochondrial complex II can generate reactive oxygen species at high rates in both the forward and reverse reactions.

Author

Quinlan CL, Orr AL, Perevoshchikova IV, Treberg JR, Ackrell BA, and Brand MD

Subjects

Hydrogen Peroxide metabolism, Electron Transport Complex II metabolism, Mitochondria metabolism, Reactive Oxygen Species metabolism

Abstract

Respiratory complex II oxidizes succinate to fumarate as part of the Krebs cycle and reduces ubiquinone in the electron transport chain. Previous experimental evidence suggested that complex II is not a significant contributor to the production of reactive oxygen species (ROS) in isolated mitochondria or intact cells unless mutated. However, we find that when complex I and complex III are inhibited and succinate concentration is low, complex II in rat skeletal muscle mitochondria can generate superoxide or H(2)O(2) at high rates. These rates approach or exceed the maximum rates achieved by complex I or complex III. Complex II generates these ROS in both the forward reaction, with electrons supplied by succinate, and the reverse reaction, with electrons supplied from the reduced ubiquinone pool. ROS production in the reverse reaction is prevented by inhibition of complex II at either the ubiquinone-binding site (by atpenin A5) or the flavin (by malonate), whereas ROS production in the forward reaction is prevented by malonate but not by atpenin A5, showing that the ROS from complex II arises only from the flavin site (site II(F)). We propose a mechanism for ROS production by complex II that relies upon the occupancy of the substrate oxidation site and the reduction state of the enzyme. We suggest that complex II may be an important contributor to physiological and pathological ROS production.

Published

2012

7. A reduction in ATP demand and mitochondrial activity with neural differentiation of human embryonic stem cells.

Author

Birket MJ, Orr AL, Gerencser AA, Madden DT, Vitelli C, Swistowski A, Brand MD, and Zeng X

Subjects

Adaptor Proteins, Signal Transducing metabolism, Carrier Proteins metabolism, Cell Proliferation, Culture Media, Conditioned, Energy Metabolism, Heat-Shock Proteins metabolism, Humans, Nuclear Proteins metabolism, Nuclear Receptor Interacting Protein 1, Oxidative Phosphorylation, Peroxisome Proliferator-Activated Receptor Gamma Coactivator 1-alpha, RNA-Binding Proteins, Transcription Factors metabolism, Adenosine Triphosphate metabolism, Cell Differentiation, Embryonic Stem Cells metabolism, Embryonic Stem Cells ultrastructure, Mitochondria metabolism, Mitochondria ultrastructure, Neural Stem Cells metabolism, Neural Stem Cells ultrastructure

Abstract

Here, we have investigated mitochondrial biology and energy metabolism in human embryonic stem cells (hESCs) and hESC-derived neural stem cells (NSCs). Although stem cells collectively in vivo might be expected to rely primarily on anaerobic glycolysis for ATP supply, to minimise production of reactive oxygen species, we show that in vitro this is not so: hESCs generate an estimated 77% of their ATP through oxidative phosphorylation. Upon differentiation of hESCs into NSCs, oxidative phosphorylation declines both in absolute rate and in importance relative to glycolysis. A bias towards ATP supply from oxidative phosphorylation in hESCs is consistent with the expression levels of the mitochondrial gene regulators peroxisome-proliferator-activated receptor γ coactivator (PGC)-1α, PGC-1β and receptor-interacting protein 140 (RIP140) in hESCs when compared with a panel of differentiated cell types. Analysis of the ATP demand showed that the slower ATP turnover in NSCs was associated with a slower rate of most energy-demanding processes but occurred without a reduction in the cellular growth rate. This mismatch is probably explained by a higher rate of macromolecule secretion in hESCs, on the basis of evidence from electron microscopy and an analysis of conditioned media. Taken together, our developmental model provides an understanding of the metabolic transition from hESCs to more quiescent somatic cell types, and supports important roles for mitochondria and secretion in hESC biology.

Published

2011

8. Impaired mitochondrial trafficking in Huntington's disease.

Author

Li XJ, Orr AL, and Li S

Subjects

Animals, Humans, Mitochondrial Proteins metabolism, Models, Biological, Protein Transport, Huntington Disease metabolism, Mitochondria metabolism

Abstract

Impaired mitochondrial function has been well documented in Huntington's disease. Mutant huntingtin is found to affect mitochondria via various mechanisms including the dysregulation of gene transcription and impairment of mitochondrial function or trafficking. The lengthy and highly branched neuronal processes constitute complex neural networks in which there is a large demand for mitochondria-generated energy. Thus, the impaired mitochondrial trafficking in neuronal cells may play an important role in the selective neuropathology of Huntington's disease. Here we discuss the evidence for the effect of the Huntington's disease protein huntingtin on the intracellular trafficking of mitochondria and the involvement of this defective trafficking in the pathogenesis of Huntington's disease.

Published

2010

9. N-terminal mutant huntingtin associates with mitochondria and impairs mitochondrial trafficking.

Author

Orr AL, Li S, Wang CE, Li H, Wang J, Rong J, Xu X, Mastroberardino PG, Greenamyre JT, and Li XJ

Subjects

Animals, Cell Line, Cells, Cultured, Humans, Huntingtin Protein, Huntington Disease genetics, Huntington Disease pathology, Mice, Mice, Mutant Strains, Mitochondria genetics, Mitochondria pathology, Nerve Tissue Proteins genetics, Nuclear Proteins genetics, Peptide Fragments genetics, Protein Transport physiology, Huntington Disease metabolism, Mitochondria metabolism, Mutation physiology, Nerve Tissue Proteins metabolism, Nuclear Proteins metabolism, Peptide Fragments metabolism

Abstract

Huntington's disease (HD) is caused by polyglutamine (polyQ) expansion in huntingtin (htt), a large (350 kDa) protein that localizes predominantly to the cytoplasm. Proteolytic cleavage of mutant htt yields polyQ-containing N-terminal fragments that are prone to misfolding and aggregation. Disease progression in HD transgenic models correlates with age-related accumulation of soluble and aggregated forms of N-terminal mutant htt fragments, suggesting that multiple forms of mutant htt are involved in the selective neurodegeneration in HD. Although mitochondrial dysfunction is implicated in the pathogenesis of HD, it remains unclear which forms of cytoplasmic mutant htt associate with mitochondria to affect their function. Here we demonstrate that specific N-terminal mutant htt fragments associate with mitochondria in Hdh(CAG)150 knock-in mouse brain and that this association increases with age. The interaction between soluble N-terminal mutant htt and mitochondria interferes with the in vitro association of microtubule-based transport proteins with mitochondria. Mutant htt reduces the distribution and transport rate of mitochondria in the processes of cultured neuronal cells. Reduced ATP level was also found in the synaptosomal fraction isolated from Hdh(CAG)150 knock-in mouse brain. These findings suggest that specific N-terminal mutant htt fragments, before the formation of aggregates, can impair mitochondrial function directly and that this interaction may be a novel target for therapeutic strategies in HD.

Published

2008

10. Neuronal Apolipoprotein E4 Expression Results in Proteome-Wide Alterations and Compromises Bioenergetic Capacity by Disrupting Mitochondrial Function

Author

Orr, Adam L, Kim, Chaeyoung, Jimenez-Morales, David, Newton, Billy W, Johnson, Jeffrey R, Krogan, Nevan J, Swaney, Danielle L, Mahley, Robert W, and Swerdlow, Russell

Subjects

Aging, Proteome, Physiological, Apolipoprotein E4, Clinical Sciences, Neurodegenerative, Stress, Alzheimer's Disease, Cell Line, Mice, Adenosine Triphosphate, mitochondrial respiration, mental disorders, Acquired Cognitive Impairment, Animals, 2.1 Biological and endogenous factors, Aetiology, protein expression, Neurons, Tumor, Neurology & Neurosurgery, neurodegeneration, Neurosciences, Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD), NAD, neuronal metabolism, Mitochondria, Brain Disorders, Neurological, lipids (amino acids, peptides, and proteins), Dementia, Cognitive Sciences, Reactive Oxygen Species, Energy Metabolism, Transcriptome, human activities, Alzheimer’s disease, apoE4

Abstract

Apolipoprotein (apo) E4, the major genetic risk factor for Alzheimer's disease (AD), alters mitochondrial function and metabolism early in AD pathogenesis. When injured or stressed, neurons increase apoE synthesis. Because of its structural difference from apoE3, apoE4 undergoes neuron-specific proteolysis, generating fragments that enter the cytosol, interact with mitochondria, and cause neurotoxicity. However, apoE4's effect on mitochondrial respiration and metabolism is not understood in detail. Here we used biochemical assays and proteomic profiling to more completely characterize the effects of apoE4 on mitochondrial function and cellular metabolism in Neuro-2a neuronal cells stably expressing apoE4 or apoE3. Under basal conditions, apoE4 impaired respiration and increased glycolysis, but when challenged or stressed, apoE4-expressing neurons had 50% less reserve capacity to generate ATP to meet energy requirements than apoE3-expressing neurons. ApoE4 expression also decreased the NAD+/NADH ratio and increased the levels of reactive oxygen species and mitochondrial calcium. Global proteomic profiling revealed widespread changes in mitochondrial processes in apoE4 cells, including reduced levels of numerous respiratory complex subunits and major disruptions to all detected subunits in complex V (ATP synthase). Also altered in apoE4 cells were levels of proteins related to mitochondrial endoplasmic reticulum-associated membranes, mitochondrial fusion/fission, mitochondrial protein translocation, proteases, and mitochondrial ribosomal proteins. ApoE4-induced bioenergetic deficits led to extensive metabolic rewiring, but despite numerous cellular adaptations, apoE4-expressing neurons remained vulnerable to metabolic stress. Our results provide insights into potential molecular targets of therapies to correct apoE4-associated mitochondrial dysfunction and altered cellular metabolism.

Published

2019

11. Sites of superoxide and hydrogen peroxide production during fatty acid oxidation in rat skeletal muscle mitochondria.

Author

Perevoshchikova, Irina V., Quinlan, Casey L., Orr, Adam L., Gerencser, Akos A., and Brand, Martin D.

Subjects

*SUPEROXIDES, *HYDROGEN peroxide, *FATTY acid oxidation, *SKELETAL muscle, *MITOCHONDRIA, *LABORATORY rats

Abstract

H2O2 production by skeletal muscle mitochondria oxidizing palmitoylcarnitine was examined under two conditions: the absence of respiratory chain inhibitors and the presence of myxothiazol to inhibit complex III. Without inhibitors, respiration and H2O2 production were low unless carnitine or malate was added to limit acetyl-CoA accumulation. With palmitoylcarnitine alone, H2O2 production was dominated by complex II (44% from site IIF in the forward reaction); the remainder was mostly from complex I (34%, superoxide from site IF). With added carnitine, H2O2 production was about equally shared between complexes I, II, and III. With added malate, it was 75% from complex III (superoxide from site IIIQo) and 25% from site IF. Thus complex II (site IIF in the forward reaction) is a major source of H2O2 production during oxidation of palmitoylcarnitine ± carnitine. Under the second condition (myxothiazol present to keep ubiquinone reduced), the rates of H2O2 production were highest in the presence of palmitoylcarnitine ± carnitine and were dominated by complex II (site IIF in the reverse reaction). About half the rest was from site IF, but a significant portion, ∼40pmol H2O2·min−1·mg protein−1, was not from complex I, II, or III and was attributed to the proteins of β-oxidation (electron-transferring flavoprotein (ETF) and ETF-ubiquinone oxidoreductase). The maximum rate from the ETF system was ∼200pmol H2O2·min−1·mg protein−1 under conditions of compromised antioxidant defense and reduced ubiquinone pool. Thus complex II and the ETF system both contribute to H2O2 productionduring fatty acid oxidation under appropriate conditions. [ABSTRACT FROM AUTHOR]

Published

2013

12. Native rates of superoxide production from multiple sites in isolated mitochondria measured using endogenous reporters

Author

Quinlan, Casey L., Treberg, Jason R., Perevoshchikova, Irina V., Orr, Adam L., and Brand, Martin D.

Subjects

*MITOCHONDRIA, *REACTIVE oxygen species, *DINITROBENZENES, *SUPEROXIDE dismutase, *FLAVINS, *HYDROQUINONE, *ADENOSINE triphosphate

Abstract

Abstract: Individual sites of superoxide production in the mitochondrial respiratory chain have previously been defined and partially characterized using specific inhibitors, but the native contribution of each site to total superoxide production in the absence of inhibitors is unknown. We estimated rates of superoxide production (measured as H2O2) at various sites in rat muscle mitochondria using specific endogenous reporters. The rate of superoxide production by the complex I flavin (site IF) was calibrated to the reduction state of endogenous NAD(P)H. Similarly, the rate of superoxide production by the complex III site of quinol oxidation (site IIIQo) was calibrated to the reduction state of endogenous cytochrome b 566. We then measured the endogenous reporters in mitochondria oxidizing NADH-generating substrates, without added respiratory inhibitors, with and without ATP synthesis. We used the calibrated reporters to calculate the rates of superoxide production from sites IF and IIIQo. The calculated rates of superoxide production accounted for much of the measured overall rates. During ATP synthesis, site IF was the dominant superoxide producer. Under nonphosphorylating conditions, overall rates were higher, and sites IF and IIIQo and unidentified sites (perhaps the complex I site of quinone reduction, site IQ) all made substantial contributions to measured H2O2 production. [Copyright &y& Elsevier]

Published

2012