Aspects Of Mitochondrial Function Research Articles

Truncated tau and Aβ cooperatively impair mitochondria in primary neurons

Mitochondrial dysfunction is likely a significant contributing factor to Alzheimer disease pathogenesis, and both amyloid peptide (Aβ) and pathological forms of tau may contribute to this impairment. Cleavage of tau at Asp421 occurs early in Alzheimer disease, and Asp421-cleaved tau likely negatively impacts neuronal function. Previously we showed that expression of Asp421-cleaved tau in a neuronal cell model resulted in mitochondrial impairment. To extend these findings we expressed either full length tau or Asp421-cleaved tau (truncated tau) in primary cortical neurons and measured different aspects of mitochondrial function with or without the addition of sublethal concentrations of Aβ. The expression of truncated tau alone induced significant mitochondrial fragmentation in neurons. When truncated tau expression was combined with Aβ at sublethal concentrations, increases in the stationary mitochondrial population and the levels of oxidative stress in cortical neurons were observed. Truncated tau expression also enhanced Aβ-induced mitochondrial potential loss in primary neurons. These new findings show that Asp421-cleaved tau and Aβ cooperate to impair mitochondria, which likely contributes to the neuronal dysfunction in Alzheimer disease.

A protective effect of melatonin on intestinal permeability is induced by diclofenac via regulation of mitochondrial function in mice

This study investigated the effect of intragastrically administered melatonin on intestinal mucosal permeability induced by diclofenac in mice. Intestinal mucosal permeability was induced in mice by intragastric administration of diclofenac (2.5 mg/kg). Melatonin was given intragastrically (10 mg/kg) once per day for 3 d after diclofenac administration. The small intestine was examined macroscopically and microscopically for pathologic injury to the intestinal mucosa. Intestinal mucosal permeability was evaluated by Evans blue and FITC-dextran methods. Mitochondrial functional parameters, including mitochondrial membrane potential, mitochondrial ATPase and succinate dehydrogenase (SDH) activity, were assessed. The malondialdehyde (MDA) and myeloperoxidase (MPO) levels were determined from small intestinal mucosal homogenates. As compared with control mice, the permeability, pathologic score, MDA and MPO levels and ulceration of the intestinal mucosa were increased significantly by diclofenac treatment, and a broadened junctional complex and enlarged intercellular space were observed by transmission electron microscopy (TEM). Melatonin treatment significantly reduced the intestinal mucosal permeability, pathologic score, MDA, and MPO levels and ulceration of the intestinal mucosa. By TEM, the small intestine villus morphology and intercellular spaces were nearly normal in melatonin-treated mice. At the level of the mitochondria, melatonin treatment significantly restored the activities of ATPase and SDH. The intestinal damage and increased intestinal permeability induced by diclofenac in mice was limited by melatonin; moreover, melatonin preserved several aspects of mitochondrial function.

Mitochondrial Fe-S cluster biogenesis, frataxin and the modulation of susceptibility to drug-induced cardiomyopathy

The role of energy deficits in the development and progression of heart failure is well-established and cardiac high-energy phosphate levels correlate directly with survival in cardiomyopathy patients [1]. In light of these clinical observations it has been posited that the modulation of mitochondrial function may be a feasible strategy to ameliorate heart failure. Aspects of mitochondrial function that have been manipulated to investigate this include: modulation of energy substrate utilization; activation of mitochondrial biogenesis; induction of mitochondrial antioxidant defenses and suppression of mitochondrial death programs including apoptosis and mitochondrial permeability transition. As briefly discussed below, targeting distinct aspects of these programs result in variable levels of success and suggest that our understanding of the role of the mitochondria in the pathophysiology remains incomplete. Pharmacologic approaches to modulate mitochondrial function have, to date, been limited and have recently been reviewed [2,3]. To identify potential novel therapeutic targets, genetic approaches have been used to directly modulate mitochondrial programming with the subsequent assessment of cardiac effects. These include the genetic augmentation of PGC-1α, the master regulator of mitochondrial biogenesis. Here, somewhat counterintuitively, acute and chronic upregulation of PGC-1α results in deleterious cardiac phenotype [4,5]. In contrast, the overexpression of mitochondrial transcription factor A ameliorates the development of ischemia-induced heart failure [6]. The genetic modulation of substrate utilization similarly exhibit divergent effects. The upregulation of atranscription factor promoting fatty acid oxidation, a known major cardiac source of energy, is detrimental [7], whereas the promotion of glucose uptake enhances cardiac tolerance to ischemia [8]. Other approaches include augmentation of anti-oxidant enzymes, e.g., by the upregulation of cardiac manganese superoxide. These transgenic mice are protected against doxorubicin-induced [9] and diabetic cardiomyopathy [10]. Augmentation of cardiac anti-apoptotic programming by the overexpression of Bcl-2 similarly restores mitochondrial function and reduces cardiomyopathy in desmin null mice [11]. In light of incomplete characterization of proteins involved in the mitochondrial permeability transition (MPT) the genetic modulation of this program to prevent cardiomyopathy has to my knowledge not being explored. However, pharmacologic inhibition of MPT by cyclosporine A attenuates cardiomyopathy and mitochondrial genomic mutagenesis in mice harboring a cardiac specific defect in mitochondrial DNA proofreading [12]. Taken together, these pharmacologic and genetic approaches are beginning to discern distinct levels at which mitochondrial reprogramming may have beneficial effects in preventing the development and progression of heart failure. An intriguing new finding, by Shultz et al is published in AGING regarding the induction of frataxin. Mutations in frataxin result in the development of Friedreich's Ataxia, an inherited neurodegenerative disease associated with the development of severe cardiomyopathy. Frataxin, itself is involved in mitochondrial iron-sulphur cluster biogenesis which functions, in part, to incorporate appropriate amounts of iron into mitochondrial proteins including aconitase and succinate dehydrogenase [13]. Whether frataxin functions as an iron-chaperone protein or plays a regulatory role in controlling iron and sulphur flux within mitochondria is not yet completely characterized. Nevertheless, the study by Shultz and colleagues [14] shows that increased cardiac frataxin enhances tricarboxylic acid cycle function resulting in increased cardiac ATP, NADH, NADPH and reduced glutathione levels. This array of features is consistent with an enhanced bioenergetic capacity and increased antioxidant defenses. The authors go on to demonstrate that overexpression of frataxin is cardioprotective against doxorubicin-induced cardiomyopathy. This intriguing study shows that the modulation of the mitochondria at the fundamental level of integrating cofactors required for protein functional integrity have beneficial effects in disease processes that are exacerbated by mitochondrial dysfunction. This study further highlights the complexity of mitochondrial function and adds a new level of regulation operational in the pathophysiology of heart failure that may be amenable to therapeutic modulation.

Metabolic Depression and Increased Reactive Oxygen Species Production by Isolated Mitochondria at Moderately Lower Temperatures

Temperature (T) reduction increases lifespan, but the mechanisms are not understood. Because reactive oxygen species (ROS) contribute to aging, we hypothesized that lowering T might decrease mitochondrial ROS production. We measured respiratory response and ROS production in isolated mitochondria at 32, 35, and 37 °C. Lowering T decreased the rates of resting (state 4) and phosphorylating (state 3) respiration phases. Surprisingly, this respiratory slowdown was associated with an increase of ROS production and hydrogen peroxide release and with elevation of the mitochondrial membrane potential, ΔΨ(m). We also found that at lower T mitochondria produced more carbon-centered lipid radicals, a species known to activate uncoupling proteins. These data indicate that reduced mitochondrial ROS production is not one of the mechanisms mediating lifespan extension at lower T. They suggest instead that increased ROS leakage may mediate mitochondrial responses to hypothermia.

Unraveling Environmental Effects on Mitochondria

Look into any cell today, and you’ll see remnants of ancient bacteria by the thousands. These mitochondria—tiny organelles in the cell that each possess their own DNA—have come under a growing scientific spotlight; scientists increasingly believe they play a central role in many, if not most, human illnesses. Exquisitely sensitive to environmental threats, mitochondria convert dietary sugars into a high-energy molecule—adenosine triphosphate (ATP)—that cells use as fuel. And when mitochondria falter, cells lose power, just as a flashlight dims when its batteries weaken. Now scientists are linking environmental interactions with the mitochondria to an array of metabolic and age-related maladies, including cancer, autism, type 2 diabetes, Alzheimer disease, Parkinson disease, and cardiovascular illness.

Theophylline treatment improves mitochondrial function after upper cervical spinal cord hemisection

The importance of mitochondria in spinal cord injury has mainly been attributed to their participation in apoptosis at the site of injury. But another aspect of mitochondrial function is the generation of more than 90% of cellular energy in the form of ATP, mediated by the oxidative phosphorylation (OxPhos) process. Cytochrome c oxidase (CcO) is a central OxPhos component and changes in its activity reflect changes in energy demand. A recent study suggests that respiratory muscle function in chronic obstructive pulmonary disease (COPD) patients is compromised via alterations in mitochondrial function. In an animal model of cervical spinal cord hemisection (C2HS) respiratory dysfunction, we have shown that theophylline improves respiratory function. In the present study, we tested the hypothesis that theophylline improves respiratory function at the cellular level via improved mitochondrial function in the C2HS model. We demonstrate that CcO activity was significantly (33%) increased in the spinal cord adjacent to the site of injury (C3-C5), and that administration of theophylline (20 mg/kg 3x daily orally) after C2HS leads to an even more pronounced increase in CcO activity of 62% compared to sham-operated animals. These results are paralleled by a significant increase in cellular ATP levels (51% in the hemidiaphragm ipsilateral to the hemisection). We conclude that C2HS increases energy demand and activates mitochondrial respiration, and that theophylline treatment improves energy levels through activation of the mitochondrial OxPhos process to provide energy for tissue repair and functional recovery after paralysis in the C2HS model.

Hydroxide Ion Channel Controls Uncoupling and Thermogenesis of Brown Fat Mitochondria

Uncoupling proteins (UCP1- UCP5) are six-transmembrane-domain transport proteins of the inner mitochondrial membrane (IMM). They increase electrical conductance of the IMM, thus dissipating the electrochemical proton gradient across this membrane and uncoupling mitochondrial respiration and ATP synthesis. By controlling mitochondrial membrane potential, UCPs can affect many aspects of mitochondrial function and have been implicated in regulation of body's energy efficiency, reducing fat depositions, thermogenesis, diabetes, and protecting the cell against oxidative damage and ageing. The founding member of the family, UCP1, is specifically expressed in brown adipose tissue (BAT) and is responsible for adaptive thermogenesis mediated by this tissue. Due to its unusually high level of expression, upon activation UCP1 completely uncouples BAT mitochondria and converts the energy of the substrate oxidation into heat. Since UCP1 can dissipate large amounts of energy, it has attracted attention as a potential target to treat obesity. In spite of their physiological and therapeutic significance, the mechanism of operation of uncoupling proteins including their ionic selectivity has long remained unknown due to the lack of direct methods to study their activity in their native membrane environment. Here, by applying the patch-clamp technique to the whole inner membrane of BAT mitochondria and for the first time directly measuring transmembrane currents produced by UCP1, we show that UCP1 is a ligand-gated hydroxide (OH-) ion channel activated by fatty acids. UCP1 is the only hydroxide ion channel reported to date. Thus, BAT thermogenesis involves the outward transport of protons by the electron transport chain along with the outward transport of OH- by UCP1, thereby amounting to cycling of water across the IMM and not to futile cycling of protons as was largely considered before.

Dependence of ER-Mitochondria Calcium Transfer on Different IP3 Receptor Isoforms

IP3 receptors (IP3Rs) release Ca2+ from the ER, which is locally relayed to the mitochondria to control several aspects of mitochondrial function. Recent studies have suggested that type 3 IP3Rs (IP3R3) are particularly important for mediating the Ca2+ transfer at the ER-mitochondrial interface. We set out to systematically evaluate the respective role of each IP3R isoform in chicken DT40 cell lines that express only one IP3R isoform (double-knockout, DKO1, DKO2 and DKO3) or provide a null-background (triple-knockout, TKO) for analysis of mammalian IP3Rs and their mutants.

Sod2 overexpression preserves myoblast mitochondrial mass and function, but not muscle mass with aging

Mice lacking superoxide dismutase-2 (SOD2 or MnSOD) die during embryonic or early neonatal development, with diffuse superoxide-induced mitochondrial damage. Although stem and progenitor cells are exquisitely sensitive to oxidant stress, they have not been well studied in MnSOD2-manipulated mouse models. Patterns of proliferation and differentiation of cultured myoblasts (muscle progenitor cells), PI3-Akt signaling during differentiation, and the maintenance of mitochondrial mass with aging using myoblasts from young (3-4 week old) and aged (27-29 months old) MnSOD2-overexpressing (Sod2-Tg) and heterozygote (Sod2(+/-)) mice were characterized by us. Overexpression of MnSOD2 in myoblasts had a protective effect on mitochondrial DNA abundance and some aspects of mitochondrial function with aging, and preservation of differentiation potential. Sod2 deficiency resulted in defective signaling in the PI3-Akt pathway, specifically impaired phosphorylation of Akt at Ser473 and Thr308 in young myoblasts, and decreased differentiation potential. Compared with young myoblasts, aged myoblast Akt was constitutively phosphorylated, unresponsive to mitogen signaling, and indifferent to MnSOD2 levels. These data suggest that specific sites in the PI3K-Akt pathway are more sensitive to increased superoxide levels than to the increased hydrogen peroxide levels generated in Sod2-transgenic myoblasts. In wild-type myoblasts, aging was associated with significant loss of mitochondrial DNA relative to chromosomal DNA, but MnSOD2 overexpression was associated with maintained myoblast mitochondrial DNA with aging.

The role of abnormal mitochondrial dynamics in the pathogenesis of Alzheimer’s disease

Mitochondria play critical roles in neuronal function and almost all aspects of mitochondrial function are altered in Alzheimer neurons. Emerging evidence shows that mitochondria are dynamic organelles that undergo continuous fission and fusion, the balance of which not only controls mitochondrial morphology and number, but also regulates mitochondrial function and distribution. In this review, after a brief overview of the basic mechanisms involved in the regulation of mitochondrial fission and fusion and how mitochondrial dynamics affects mitochondrial function, we will discuss in detail our and others' recent work demonstrating abnormal mitochondrial morphology and distribution in Alzheimer's disease (AD) models and how these abnormalities may contribute to mitochondrial and synaptic dysfunction in AD. We propose that abnormal mitochondrial dynamics plays a key role in causing the dysfunction of mitochondria that ultimately damage AD neurons.

Testicular mitochondrial alterations in untreated streptozotocin-induced diabetic rats

Diabetes-induced complications are associated with mitochondrial dysfunction and increasing evidence suggests that diabetes has an adverse effect on male reproductive function. The STZ-induced diabetic rat was used as an animal model for the type 1 form of the disease with the aim of determining its effects in spermatogenesis and testicular mitochondrial function. Several aspects of mitochondrial function were measured, including respiratory and electric potential function, as well as mitochondrial calcium loading capacity. Additionally oxidative stress production, antioxidant levels and possible apoptotic alterations were also evaluated. We observed that diabetic animals present alterations in spermatogenesis in both the testis and epidydimus. However, and surprisingly, the overall results in mitochondrial parameters failed to reveal severe testicular mitochondrial dysfunction in diabetic animals, with the exception of a decrease in calcium load. Taken together, results suggest that in animal models that mimic untreated type 1 diabetes the severe effects of the condition on spermatogenesis are not directly mitochondrial-mediated.

Sepsis therapy: what's the best for the mitochondria?

It is suspected that mitochondrial dysfunction is a major cause of organ failure in sepsis and septic shock. A study presented in this issue of Critical Care revealed that liver mitochondria from pigs treated with norepinephrine during endotoxaemia exhibit greater in vitro respiratory activity. The investigators provide an elegant demonstration of how therapeutic interventions in sepsis may profoundly influence mitochondrial respiration, but many aspects of mitochondrial function in sepsis remain to be clarified.

Muscular mitochondrial dysfunction and type 2 diabetes mellitus

Muscular mitochondrial dysfunction, leading to the accumulation of fat in skeletal muscle, has been proposed to be involved in the development of type 2 diabetes mellitus. Here, we review human studies that investigated various aspects of mitochondrial function in relation to muscular insulin sensitivity and/or diabetes. In-vivo magnetic resonance spectroscopy allows assessment of mitochondrial functionality from adenosine triphosphate flux in the nonexercising state and from phosphocreatine recovery from (sub)maximal exercising. Application of both approaches revealed reduced mitochondrial oxidative capacity in insulin-resistant (pre)diabetic humans. Reductions in mitochondrial density may contribute to, or even underlie, these findings as well as intrinsic defects in mitochondrial respiration. So far, only two studies reported measurements of mitochondrial respiratory capacity in intact mitochondria in diabetic patients, with inconsistent findings. Muscular mitochondrial aberrations in type 2 diabetes mellitus can be detected, but it is so far unclear if these aberrations are causally related to the development of the disease. Alternatively, mitochondrial dysfunction may simply be the consequence of elevated plasma fatty acids or glucose levels.

Reversible phosphorylation of Drp1 by cyclic AMP‐dependent protein kinase and calcineurin regulates mitochondrial fission and cell death

Opposing mitochondrial fission and fusion reactions determine the shape and interconnectivity of mitochondria. Dynamin-related protein 1 (Drp1) is an ancient mechanoenzyme that uses GTP hydrolysis to power the constriction and division of mitochondria. Although Drp1-mediated mitochondrial fragmentation is recognized as an early event in the apoptotic programme, acute regulation of Drp1 activity is poorly understood. Here, we identify a crucial phosphorylation site that is conserved in all metazoan Drp1 orthologues. Ser 656 is phosphorylated by cyclic AMP-dependent protein kinase and dephosphorylated by calcineurin, and its phosphorylation state is controlled by sympathetic tone, calcium levels and cell viability. Pseudophosphorylation of Drp1 by mutation of Ser 656 to aspartic acid leads to the elongation of mitochondria and confers resistance to various pro-apoptotic insults. Conversely, the constitutively dephosphorylated Ser656Ala mutant Drp1 promotes mitochondrial fragmentation and increases cell vulnerability. Thus, Drp1 phosphorylation at Ser 656 provides a mechanism for the integration of cAMP and calcium signals in the control of mitochondrial shape, apoptosis and other aspects of mitochondrial function.

287 ACTIVE MITOCHONDRIA ARE PRESENT IN MOUSE AND MONKEY EMBRYONIC STEM CELL LINES

The inner cell mass (ICM) of the blastocyst develops into the fetus after uterine implantation. Prior to implantation, ICM cells synthesize ATP by glycolytic reactions. We now report that cells of the ICM in 3.5-day-old mouse embryos have too few mitochondria to be visualized with either Mitotracker red (active mitochondria) or an antibody against complex I of OXPHOS. By comparison, all of the surrounding trophectoderm cells reveal numerous mitochondria throughout their cytoplasm. It has largely been assumed that embryonic stem (ES) stem cells derived from the ICM also have few mitochondria, and that replication of mitochondria in the ES cells does not begin until they commence differentiation. We further report that mouse E14 ES cells and monkey ORMES 7 ES cells have considerable numbers of active mitochondria when cultured under standard conditions, i.e., 5% CO2 in air. Both the mouse E14 and monkey ES cell lines expressed two markers of undifferentiated cells, Oct-4 and SSEA-4, and monkey ES cells expressed the undifferentiated cell marker Nanog; however, Oct-4 is nonspecific in monkey ES cells because trophectoderm also expresses this marker, unlike in mice. Ninety-nine percent of the E14 cells examined, and 100% of the ORMES 7 cells, have a visible mitochondrial mass when stained with either Mitoracker red or with an antibody against OXPHOS complex I. The ATP content in the mouse E14 cells (4.13 pmoles ATP/cell) is not significantly different (P = 0.76) from that in a mouse fibroblast control (3.75 pmoles ATP/cell). Cells of the monkey ORMES 7 cell line had 61% of the ATP/cell content (7.55 pmoles ATP/cell) compared to the monkey fibroblast control (12.38 pmoles ATP/cell). Both cell lines expressed two proteins believed to indicate competence of mitochondria to replicate: PolG, the polymerase used to replicate the mitochondrial genome, and TFAM, a nuclear-encoded transcription factor reported to regulate several aspects of mitochondrial function. Both proteins were found to co-localize in the mitochondria. We conclude that when the ICMs are isolated from blastocysts and used to establish these two ES cell lines in cell culture, mitochondrial biosynthesis is activated.

Energized, Polarized, and Actively Respiring Mitochondria Are Required for Acute Leydig Cell Steroidogenesis

The first and rate-limiting step in the biosynthesis of steroid hormones is the transfer of cholesterol into mitochondria, which is facilitated by the steroidogenic acute regulatory (StAR) protein. Recent study of Leydig cell function has focused on the mechanisms regulating steroidogenesis; however, few investigations have examined the importance of mitochondria in this process. The purpose of this investigation was to determine which aspects of mitochondrial function are necessary for acute cAMP-stimulated Leydig cell steroidogenesis. MA-10 cells were treated with 8-bromoadenosine 3',5'-cyclic monophosphate (cAMP) and different site-specific agents that disrupt mitochondrial function, and the effects on acute cAMP-stimulated progesterone synthesis, StAR mRNA and protein, mitochondrial membrane potential (Deltapsim), and ATP synthesis were determined. cAMP treatment of MA-10 cells resulted in significant increases in both cellular respiration and Deltapsim. Dissipating Deltapsim with carbonyl cyanide m-chlorophenyl hydrazone resulted in a profound reduction in progesterone synthesis, even in the presence of newly synthesized StAR protein. Preventing electron transport in mitochondria with antimycin A significantly reduced cellular ATP, potently inhibited steroidogenesis, and reduced StAR protein levels. Inhibiting mitochondrial ATP synthesis with oligomycin reduced cellular ATP, inhibited progesterone synthesis and StAR protein, but had no effect on Deltapsim. Disruption of intramitochondrial pH with nigericin significantly reduced progesterone production and StAR protein but had minimal effects on Deltapsim. 22(R)-hydroxycholesterol-stimulated progesterone synthesis was not inhibited by any of the mitochondrial reagents, indicating that neither P450 side-chain cleavage nor 3beta-hydroxysteroid dehydrogenase activity was inhibited. These results indicate that Deltapsim, mitochondrial ATP synthesis, and mitochondrial pH are all required for acute steroid biosynthesis. These results suggest that mitochondria must be energized, polarized, and actively respiring to support Leydig cell steroidogenesis, and alterations in the state of mitochondria may be involved in regulating steroid biosynthesis.

Mitochondrial Function in Leydig Cell Steroidogenesis

The first and rate-limiting step in the biosynthesis of steroid hormones is the transfer of cholesterol into mitochondria, which is facilitated by the steroidogenic acute regulatory (StAR) protein. Recent studies of Leydig cell function have focused on the molecular events controlling steroidogenesis; however, few studies have examined the importance of the mitochondria. The purpose of this investigation was to determine which aspects of mitochondrial function are necessary for Leydig cell steroidogenesis. MA-10 tumor Leydig cells were treated with 8-bromo-cAMP (cAMP) and site-specific mitochondrial disrupters, pro-oxidants, and their effects on progesterone synthesis, StAR expression, mitochondrial membrane potential (delta psi(m)) and ATP synthesis were determined. Dissipating delta psi(m) with CCCP inhibited progesterone synthesis, even in the presence of newly synthesized StAR protein. The electron transport inhibitor antimycin A significantly reduced cellular ATP, inhibited steroidogenesis, and reduced StAR protein expression. The F0/F1 ATPase inhibitor oligomycin reduced cellular ATP and inhibited progesterone synthesis and StAR protein expression, but had no effect on delta psi(m). Disruption of pH with nigericin significantly reduced progesterone production and StAR protein, but had minimal effects on delta psi(m). Sodium arsenite at low concentrations inhibited StAR protein but not mRNA expression and inhibited progesterone without disrupting delta psi(m). The mitochondrial Ca2+ inhibitor Ru360 also inhibited StAR protein expression. These results demonstrate that delta psi(m), ATP synthesis, delta pH and [Ca2+]mt are all required for steroid biosynthesis, and that mitochondria are sensitive to oxidative stress. These results suggest that mitochondria must be energized, polarized, and actively respiring to support Leydig cell steroidogenesis and alterations in the state of mitochondria may be involved in regulating steroid biosynthesis.

Highlights of the National Cancer Institute Workshop on Mitochondrial Function and Cancer

This workshop was stimulated by the desire of the National Cancer Institute to examine various aspects of mitochondrial function as they relate to tumorigenesis, apoptosis, and cancer therapy. Through endosymbiosis, a bacterial ancestor took its position in the eukaryotic cytoplasm and serves as the

The effects of complex I function and oxidative damage on lifespan and anesthetic sensitivity in Caenorhabditis elegans

A mutation in a subunit of complex I of the mitochondrial electron transport chain ( gas-1) causes Caenorhabditis elegans to be hypersensitive to volatile anesthetics and oxygen as well as shortening lifespan. We hypothesized that changes in mitochondrial respiration or reactive oxygen species production cause these changes. Therefore, we compared gas-1 to other mitochondrial mutants to identify the relative importance of these two aspects of mitochondrial function in determining longevity. Lifespans of gas-1 and mev-1 were decreased compared with N2, while that of clk-1 was increased. Rates of oxidative phosphorylation were decreased in all three mutants, but the ROS damage was decreased only in clk-1. Suppressors of gas-1 increased rates of oxidative phosphorylation, decreased oxidative damage to mitochondrial proteins and increased lifespan. Two strains containing combinations of mutations predicted to have very decreased complex I function, had unexpectedly long lifespans. We conclude that mitochondrial changes in lifespan appear to be mediated primarily by changes in oxidative damage rather than by changes in rates of oxidative phosphorylation. In contrast, the effects of mitochondrial changes on anesthetic sensitivity appear to be mediated by both altered respiration and oxidative damage.

The effects of complex I function and oxidative damage on lifespan and anesthetic sensitivity in Caenorhabditis elegans

A mutation in a subunit of complex I of the mitochondrial electron transport chain (gas-1) causes Caenorhabditis elegans to be hypersensitive to volatile anesthetics and oxygen as well as shortening lifespan. We hypothesized that changes in mitochondrial respiration or reactive oxygen species production cause these changes. Therefore, we compared gas-1 to other mitochondrial mutants to identify the relative importance of these two aspects of mitochondrial function in determining longevity. Lifespans of gas-1 and mev-1 were decreased compared with N2, while that of clk-1 was increased. Rates of oxidative phosphorylation were decreased in all three mutants, but the ROS damage was decreased only in clk-1. Suppressors of gas-1 increased rates of oxidative phosphorylation, decreased oxidative damage to mitochondrial proteins and increased lifespan. Two strains containing combinations of mutations predicted to have very decreased complex I function, had unexpectedly long lifespans. We conclude that mitochondrial changes in lifespan appear to be mediated primarily by changes in oxidative damage rather than by changes in rates of oxidative phosphorylation. In contrast, the effects of mitochondrial changes on anesthetic sensitivity appear to be mediated by both altered respiration and oxidative damage.