Mitochondrial Electron Transport Chain Proteins Research Articles

Vagus nerve contributes to the development of steatohepatitis and obesity in phosphatidylethanolamine N-methyltransferase deficient mice

Phosphatidylethanolamine N-methyltransferase (PEMT), a liver enriched enzyme, is responsible for approximately one third of hepatic phosphatidylcholine biosynthesis. When fed a high-fat diet (HFD), Pemt(-/-) mice are protected from HF-induced obesity; however, they develop steatohepatitis. The vagus nerve relays signals between liver and brain that regulate peripheral adiposity and pancreas function. Here we explore a possible role of the hepatic branch of the vagus nerve in the development of diet induced obesity and steatohepatitis in Pemt(-/-) mice. 8-week old Pemt(-/-) and Pemt(+/+) mice were subjected to hepatic vagotomy (HV) or capsaicin treatment, which selectively disrupts afferent nerves, and were compared to sham-operated or vehicle-treatment, respectively. After surgery, mice were fed a HFD for 10 weeks. HV abolished the protection against the HFD-induced obesity and glucose intolerance in Pemt(-/-) mice. HV normalized phospholipid content and prevented steatohepatitis in Pemt(-/-) mice. Moreover, HV increased the hepatic anti-inflammatory cytokine interleukin-10, reduced chemokine monocyte chemotactic protein-1 and the ER stress marker C/EBP homologous protein. Furthermore, HV normalized the expression of mitochondrial electron transport chain proteins and of proteins involved in fatty acid synthesis, acetyl-CoA carboxylase and fatty acid synthase in Pemt(-/-) mice. However, disruption of the hepatic afferent vagus nerve by capsaicin failed to reverse either the protection against the HFD-induced obesity or the development of HF-induced steatohepatitis in Pemt(-/-) mice. Neuronal signals via the hepatic vagus nerve contribute to the development of steatohepatitis and protection against obesity in HFD fed Pemt(-/-) mice.

Abstract 945: Genetic association study of the mitochondrial genome and colorectal cancer risk: The Multiethnic Cohort

Abstract Background: The mitochondrial genome is highly specialized, encoding essential mitochondrial electron transport chain proteins required for aerobic metabolism, and involved in free radical production—two pathways that are involved in carcinogenesis. The role of the mitochondrial genome in colorectal cancer susceptibility has yet to be fully examined. We comprehensively characterized the genetic variation across the 16kb mitochondrial genome across five ancestral populations and examined the association between mitochondrial SNPs (mtSNPs) and colorectal cancer risk in a multiethnic population. Methods: We compiled mitochondrial sequencing data from the public domain for African, Asian, European, and Latino populations, and sequenced the mitochondrial genomes of 160 Native Hawaiians. A total of 863 mtSNPs (MAF>1%) were identified and genotyped in a multiethnic validation panel, identifying 621 mtSNPs with working assays and resulting in 446 mtSNPs detected in at least one sample. A total of 186 mtSNPs were prioritized based on MAF>∼2% for genotyping in a case-control study of colorectal cancer nested in the Multiethnic Cohort (cases/controls=1,923/10,555). To evaluate the association between mtSNPs and colorectal cancer risk, odds ratios (OR) and 95% confidence intervals (CI) were estimated by unconditional logistic regression, adjusting for age, sex, and maternal self-reported ancestry. Stratified analysis were conducted by maternal self-reported ancestry given the wide variation in allele frequencies across ancestral groups. A Bonferroni-corrected p-value of 8.77x10-5 was used to determine statistical significance of associations given the number of mtSNPs tested and stratified analyses. Results: At a nominal P<0.05, 12 of 175 mtSNPs (MAF>1%) were associated with colorectal cancer for all groups combined, while 5 of 114 mtSNPs, 1 of 45 mtSNPs, 7 of 65 mtSNPs, 42 of 101 mtSNPs, and 12 of 70 mtSNPs were associated among African Americans, Native Hawaiians, Asian Americans, Latinos, and European Americans, respectively. Statistically significant associations with colorectal cancer were observed with seven mtSNPs (four largely independent signals) among Latinos (P<8.5x10-5). Among Latinos, the most significant association was observed with mt769 that is located within the gene that encodes for the 16s rRNA (OR=0.36; 95% CI: 0.23-0.55, P=5x10-6); this association remained statistically significant with adjustment for genetic ancestry based on nuclear DNA encoded ancestry informative markers. Conclusion: Our study suggests that inherited variants of the mitochondrial genome may be associated with colorectal cancer risk in specific ancestral populations. Future work will further address population stratification of the mitochondrial genome, as well as investigate haplogroup associations and the cumulative effects of mitochondrial genes on colorectal cancer susceptibility. Citation Format: Iona C. Cheng, Christian Caberto, Kenneth Beckman, Annette Lum-Jones, Christopher Haiman, Loic Le Marchand, Daniel Stram, Richa Saxena. Genetic association study of the mitochondrial genome and colorectal cancer risk: The Multiethnic Cohort. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 945. doi:10.1158/1538-7445.AM2014-945

Abstract 9841: Expression of Mitochondrial Fusion Proteins is Increased in Hibernating Hearts Following Bypass Surgery

Background: Based on clinical studies, regional function within hibernating myocardium may not return to normal immediately following successful bypass surgery (CABG). We hypothesized that the mitochondrial proteome within chronically ischemic hibernating hearts does not fully recover early post-CABG and may in part, contribute to submaximal myocardial oxygen expenditure. Methods: Twelve pigs underwent thoracotomy with placement of a constrictor around the LAD artery and had reduced regional function 12 weeks later. Six pigs then underwent sternotomy and off-pump revascularization with a left internal mammary artery graft to the LAD just beyond the chronic stenosis. A patent graft was confirmed by CTA at 4 weeks post-CABG. Five additional pigs underwent a SHAM operation and served as controls. Prior to sacrifice, regional blood flows by μspheres were determined at baseline and during high dose dobutamine (40 μg/kg/min). Post-sacrifice, the content of mitochondrial electron transport chain (ETC) and fusion proteins was determined by western gels. Results: In the hibernating regions that underwent CABG, maximal blood flow during dobutamine was lower than Control hearts (2.5±0.2 vs 3.5±0.2 ml/min/g; NS). As shown in the Figure, the content of mitochondrial ETC proteins, when normalized to SHAM hearts, did not recover in hibernating hearts that had undergone CABG. Compared with non-revascularized hibernating hearts however, hearts that had undergone CABG demonstrated increased expression of fusion proteins. Conclusion: Despite successful revascularization of hibernating heart tissue, maximal blood flow in response to a catecholamine challenge is submaximal at 4 weeks following CABG, at a time that the expression of ETC proteins has not recovered to normal. Mitochondrial fusion proteins are increased however, and may be an important dynamic mitochondrial process to restore maximal energetics of hibernating hearts following CABG.

Integrated Proteomic and Metabolic Analysis of Breast Cancer Progression

One of the most persistent hallmarks of cancer biology is the preference of tumor cells to derive energy through glycolysis as opposed to the more efficient process of oxidative phosphorylation (OXPHOS). However, little is known about the molecular cascades by which oncogenic pathways bring about this metabolic switch. We carried out a quantitative proteomic and metabolic analysis of the MCF10A derived cell line model of breast cancer progression that includes parental cells and derivatives representing three different tumor grades of Ras-driven cancer with a common genetic background. A SILAC (Stable Isotope Labeling by Amino acids in Cell culture) labeling strategy was used to quantify protein expression in conjunction with subcellular fractionation to measure dynamic subcellular localization in the nucleus, cytosol and mitochondria. Protein expression and localization across cell lines were compared to cellular metabolic rates as a measure of oxidative phosphorylation (OXPHOS), glycolysis and cellular ATP. Investigation of the metabolic capacity of the four cell lines revealed that cellular OXPHOS decreased with breast cancer progression independently of mitochondrial copy number or electron transport chain protein expression. Furthermore, glycolytic lactate secretion did not increase in accordance with cancer progression and decreasing OXPHOS capacity. However, the relative expression and subcellular enrichment of enzymes critical to lactate and pyruvate metabolism supported the observed extracellular acidification profiles. This analysis of metabolic dysfunction in cancer progression integrated with global protein expression and subcellular localization is a novel and useful technique for determining organelle-specific roles of proteins in disease.

Leukocyte mitochondrial DNA copy number in bipolar disorder

Evidence supports the role for mitochondrial impairment in the pathophysiology of bipolar disorder (BD). BD has been associated with decreased mitochondrial electron transport chain activity and increased oxidative stress. Also, mitochondrial DNA (mtDNA) encodes mitochondrial electron transport chain proteins and has been associated with altered oxidative stress. Preclinical studies showed that lithium treatment increased mtDNA content, but no study has directly assessed mtDNA content in subjects with BD in vivo. Also, the effects of lithium treatment on mtDNA content have never been evaluated in humans. Leukocyte mtDNA content using real time-PCR was evaluated in subjects with BD (n=23) in a depressive episode (≥18 in the 21-item Hamilton Depression Rating Scale) before and after 6-week lithium treatment versus healthy controls (n=24). mtDNA content showed no significant difference between subjects with BD at baseline and controls (p=0.46); also no difference was observed when comparing before and after lithium treatment. A trend for decreased mtDNA content was specifically observed in BD type I compared to controls and BD type II (p=0.05). Importantly, endpoint mtDNA copy number was significantly correlated with age. In BD subjects who were younger, unmedicated and had a shorter duration of illness, no change was observed in mtDNA copy number. More studies with larger samples are warranted to evaluate mtDNA content changes in BD and its potential role as a treatment target, especially in BD type I and its association with aging.

Enhanced peroxisomal β-oxidation is associated with prevention of obesity and glucose intolerance by fish oil-enriched diets

The effects of different amounts of omega 3-polyunsaturated fatty acids in diets with normal or high content of fat on lipid and carbohydrate metabolism were investigated. Mice were fed for 8 weeks on diets enriched with fish oil or lard at 10% or 60% of energy. Energy balance and energy expenditure were analyzed. Fatty acid (FA) oxidative capacity of the liver and the activity of enzymes involved in this pathway were assessed. Fish oil-fed mice had lower body weight and adiposity compared with lard-fed animals, despite having lower rates of oxygen consumption. Mice fed diets containing fish oil also displayed lower glycemia, reduced fat content in the liver, and improved glucose tolerance compared with lard-fed animals. The fish oil-containing diets increased markers of hepatic peroxisomal content and increased the generation of metabolites derived from FA β-oxidation in liver homogenates. In contrast, no changes were observed in the content of mitochondrial electron transport chain proteins or carnitine palmitoyl transferase-1 in the liver, indicating little direct effect of fish oil on mitochondrial metabolism. Collectively, our findings suggest that the energy inefficient oxidation of FAs in peroxisomes may be an important mechanism underlying the protection against obesity and glucose intolerance of fish oil administration.

Does Dietary Copper Supplementation Enhance or Diminish PCB126 Toxicity in the Rodent Liver?

Copper is essential for the function of the mitochondrial electron transport chain and several antioxidant proteins. However, in its free form copper can participate in Fenton-like reactions that produce reactive hydroxyl radicals. Aryl-hydrocarbon receptor (AhR) agonists, including the most potent polychlorinated biphenyl (PCB) congener, 3,3',4,4',5-pentachlorobiphenyl (PCB126), increase copper levels in rodent livers. This is accompanied by biochemical and toxic changes. To assess the involvement of copper in PCB toxicity, male Sprague-Dawley rats were fed an AIN-93G diet with differing dietary copper levels: low (2 ppm), adequate (6 ppm), and high (10 ppm). After three weeks, rats from each group were given a single ip injection of corn oil (control), 1, or 5 μmol/kg body weight PCB126. Two weeks following injections, biochemical and morphological markers of hepatic toxicity, trace metal status, and hepatic gene expression of metalloproteins were evaluated. Increasing dietary copper was associated with elevated tissue levels of copper and ceruloplasmin. In the livers of PCB126-treated rats, the hallmark signs of AhR activation were present, including increased cytochrome P450 and lipid levels and decreased glutathione. In addition, a doubling of hepatic copper levels was seen, and overall metal homeostasis was disturbed, resulting in decreased hepatic selenium, manganese, zinc, and iron. Expression of key metalloproteins was either decreased (cytochrome c oxidase), unchanged (ceruloplasmin and CuZnSOD), or increased (tyrosinase and metallothioneins 1 and 2) with exposure to PCB126. Increases in metallothionein may contribute/reflect the increased copper seen. Alterations in dietary copper did not amplify or abrogate the hepatic toxicity of PCB126. PCB126 toxicity, i.e., oxidative stress and steatosis, is clearly associated with disturbed metal homeostasis. Understanding the mechanisms of this disturbance may provide tools to prevent liver toxicity by other AhR agonists.

Nitric oxide regulates vascular adaptive mitochondrial dynamics.

Cardiovascular disease risk factors, such as diabetes, hypertension, dyslipidemia, obesity, and physical inactivity, are all correlated with impaired endothelial nitric oxide synthase (eNOS) function and decreased nitric oxide (NO) production. NO-mediated regulation of mitochondrial biogenesis has been established in many tissues, yet the role of eNOS in vascular mitochondrial biogenesis and dynamics is unclear. We hypothesized that genetic eNOS deletion and 3-day nitric oxide synthase (NOS) inhibition in rodents would result in impaired mitochondrial biogenesis and defunct fission/fusion and autophagy profiles within the aorta. We observed a significant, eNOS expression-dependent decrease in mitochondrial electron transport chain (ETC) protein subunits from complexes I, II, III, and V in eNOS heterozygotes and eNOS null mice compared with age-matched controls. In response to NOS inhibition with NG-nitro-L-arginine methyl ester (L-NAME) treatment in Sprague Dawley rats, significant decreases were observed in ETC protein subunits from complexes I, III, and IV as well as voltage-dependent anion channel 1. Decreased protein content of upstream regulators of mitochondrial biogenesis, cAMP response element-binding protein and peroxisome proliferator-activated receptor-γ coactivator-1α, were observed in response to 3-day L-NAME treatment. Both genetic eNOS deletion and NOS inhibition resulted in decreased manganese superoxide dismutase protein. L-NAME treatment resulted in significant changes to mitochondrial dynamic protein profiles with decreased fusion, increased fission, and minimally perturbed autophagy. In addition, L-NAME treatment blocked mitochondrial adaptation to an exercise intervention in the aorta. These results suggest that eNOS/NO play a role in basal and adaptive mitochondrial biogenesis in the vasculature and regulation of mitochondrial turnover.

Reduced expression of mitochondrial electron transport chain proteins from hibernating hearts relative to ischemic preconditioned hearts in the second window of protection

Although protection against necrosis has been observed in both hibernating (HIB) and ischemic preconditioned hearts in the second window of protection (SWOP), a comparison of the mitochondrial proteome between the two entities has not been previously performed. Anesthetized swine underwent instrumentation with a fixed constrictor around the LAD artery and were followed for 12weeks (HIB; N=7). A second group of anesthetized swine underwent ischemic preconditioning by inflating a balloon within the LAD artery 10 times for 2min, each separated by 2min reperfusion and were sacrificed 24h later (SWOP; N=7). Myocardial blood flow and high-energy nucleotides were obtained in the LAD region and normalized to remote regions. Post-sacrifice, protein content as measured with iTRAQ was compared in isolated mitochondria from the LAD area of a Sham heart. Basal regional blood flow in the LAD region when normalized to the remote region was 0.86±0.04 in HIB and 1.02±0.02 in SWOP tissue (P<0.05). Despite reduced regional blood flows in HIB hearts, ATP content in the LAD region, when normalized to the remote region was similar in HIB versus SWOP (1.06±0.06 and 1.02±0.05 respectively; NS) as was the transmural phosphocreatine (PCr) to ATP ratio (2.1±0.2 and 2.2±0.2 respectively; NS). Using iTRAQ, 64 common proteins were identified in HIB and SWOP hearts. Compared with SWOP, the relative abundance of mitochondrial proteins involved with electron transport chain (ETC) were reduced in HIB including NADH dehydrogenase, Cytochrome c reductase and oxidase, ATP synthase, and nicotinamide nucleotide transhydrogenase. Within chronically HIB heart tissue with reduced blood flow, the relative abundance of mitochondrial ETC proteins is decreased when compared with SWOP tissue. These data support the concept that HIB heart tissue subjected to chronically reduced blood flow is associated with a down-regulation in the expression of key mitochondrial proteins involved in electron transport.

An Involvement of Oxidative Stress in Endoplasmic Reticulum Stress and Its Associated Diseases

The endoplasmic reticulum (ER) is the major site of calcium storage and protein folding. It has a unique oxidizing-folding environment due to the predominant disulfide bond formation during the process of protein folding. Alterations in the oxidative environment of the ER and also intra-ER Ca2+ cause the production of ER stress-induced reactive oxygen species (ROS). Protein disulfide isomerases, endoplasmic reticulum oxidoreductin-1, reduced glutathione and mitochondrial electron transport chain proteins also play crucial roles in ER stress-induced production of ROS. In this article, we discuss ER stress-associated ROS and related diseases, and the current understanding of the signaling transduction involved in ER stress.

Altered expression of mitochondrial electron transport chain proteins and improved myocardial energetic state during late ischemic preconditioning

Altered expression of mitochondrial electron transport proteins has been shown in early preconditioned myocardial tissue. We wished to determine whether these alterations persist in the Second Window of Protection (SWOP) and if so, whether a favorable energetic state is facilitated during subsequent ischemia. Fourteen pigs underwent a SWOP protocol with ten 2-minute balloon inflations in the LAD artery, each separated by 2 minutes reperfusion. Twenty-four hours later, mitochondria were isolated from SWOP and SHAM pig hearts and analyzed for uncoupling protein (UCP)-2 content by western blot analysis, proteomic changes by iTRAQ(®) and respiration by an oxygen electrode. In parallel in vivo studies, high-energy nucleotides were obtained by transmural biopsy from anesthetized SWOP and SHAM pigs at baseline and during sustained low-flow ischemia. Compared with SHAM mitochondria, ex vivo SWOP heart tissue demonstrated increased expression of UCP-2, Complex IV (cytochrome c oxidase) and Complex V (ATPase) proteins. In comparison with SHAM pigs during in vivo conditions, transmural energetics in SWOP hearts, as estimated by the free energy of ATP hydrolysis (ΔG(0)), were similar at baseline but had decreased by the end of low-flow ischemia (-57.0 ± 2.1 versus -51.1 ± 1.4 kJ/mol; P < 0.05). In conclusion, within isolated mitochondria from preconditioned SWOP hearts, UCP-2 is increased and in concert with enhanced Complex IV and V proteins, imparts a favorable energetic state during low-flow ischemia. These data support the notion that mitochondrial adaptations that may reduce oxidant damage do not reduce the overall efficiency of energetics during sustained oxygen deprivation.

Peroxisome Proliferator-activated Receptor γ (PPARγ) Mediates a Ski Oncogene-induced Shift from Glycolysis to Oxidative Energy Metabolism

Overexpression of the Ski oncogene induces oncogenic transformation of chicken embryo fibroblasts (CEFs). However, unlike most other oncogene-transformed cells, Ski-transformed CEFs (Ski-CEFs) do not display the classical Warburg effect. On the contrary, Ski transformation reduced lactate production and glucose utilization in CEFs. Compared with CEFs, Ski-CEFs exhibited enhanced TCA cycle activity, fatty acid catabolism through β-oxidation, glutamate oxidation, oxygen consumption, as well as increased numbers and mass of mitochondria. Interestingly, expression of PPARγ, a key transcription factor that regulates adipogenesis and lipid metabolism, was dramatically elevated at both the mRNA and protein levels in Ski-CEFs. Accordingly, PPARγ target genes that are involved in lipid uptake, transport, and oxidation were also markedly up-regulated by Ski. Knocking down PPARγ in Ski-CEFs by RNA interference reversed the elevated expression of these PPARγ target genes, as well as the shift to oxidative metabolism and the increased mitochondrial biogenesis. Moreover, we found that Ski co-immunoprecipitates with PPARγ and co-activates PPARγ-driven transcription.

Sensitivity to Low-Dose/Low-LET Ionizing Radiation in Mammalian Cells Harboring Mutations in Succinate Dehydrogenase Subunit C is Governed by Mitochondria-Derived Reactive Oxygen Species

It has been hypothesized that ionizing radiation-induced disruptions in mitochondrial O₂ metabolism lead to persistent heritable increases in steady-state levels of intracellular superoxide (O₂(•U+2212)) and hydrogen peroxide (H₂O₂) that contribute to the biological effects of radiation. Hamster fibroblasts (B9 cells) expressing a mutation in the gene coding for the mitochondrial electron transport chain protein succinate dehydrogenase subunit C (SDHC) demonstrate increases in steady-state levels of O₂•- and H₂O₂. When B9 cells were exposed to low-dose/low-LET radiation (5-50 cGy), they displayed significantly increased clonogenic cell killing compared with parental cells. Clones derived from B9 cells overexpressing a wild-type human SDHC (T4, T8) demonstrated significantly increased surviving fractions after exposure to 5-50 cGy relative to B9 vector controls. In addition, pretreatment with polyethylene glycol-conjugated CuZn superoxide dismutase and catalase as well as adenoviral-mediated overexpression of MnSOD and/or mitochondria-targeted catalase resulted in significantly increased survival of B9 cells exposed to 10 cGy ionizing radiation relative to vector controls. Adenoviral-mediated overexpression of either MnSOD or mitochondria-targeted catalase alone was equally as effective as when both were combined. These results show that mammalian cells over expressing mutations in SDHC demonstrate low-dose/low-LET radiation sensitization that is mediated by increased levels of O₂•- and H₂O₂. These results also support the hypothesis that mitochondrial O₂•- and H₂O₂ originating from SDH are capable of playing a role in low-dose ionizing radiation-induced biological responses.

Mutation of Succinate Dehydrogenase Subunit C Results in Increased O2·−, Oxidative Stress, and Genomic Instability

Mutations in genes coding for succinate dehydrogenase (SDH) subunits are believed to contribute to cancer and aging, but the mechanism for this is unclear. Hamster fibroblasts expressing a mutation in SDH subunit C (SDHC; B9) showed 3-fold increases in dihydroethidine and dichlorodihydrofluorescein (CDCFH(2)) oxidation indicative of increased steady-state levels of O2(.-) and H2O2, increases in glutathione/glutathione disulfide (indicative of oxidative stress), as well as increases in superoxide dismutase activity, relative to parental B1 cells. B9 cells also showed characteristics associated with cancer cells, including aneuploidy, increases in glucose consumption, and sensitivity to glucose deprivation-induced cytotoxicity. Expression of wild-type (WT) human SDHC in B9 cells caused prooxidant production, glucose consumption, sensitivity to glucose deprivation-induced cytotoxicity, and aneuploidy to revert to the WT phenotype. These data show that SDHC mutations cause increased O2(.-) production, metabolic oxidative stress, and genomic instability and that mutations in genes coding for mitochondrial electron transport chain proteins can contribute to phenotypic changes associated with cancer cells. These results also allow for the speculation that DNA damage to genes coding for electron transport chain proteins could result in a "mutator phenotype" by increasing steady-state levels of O2(.-) and H2O2.

Sepsis Induces Diaphragm Electron Transport Chain Dysfunction and Protein Depletion

Sepsis significantly alters skeletal muscle mitochondrial function, but the mechanisms responsible for this abnormality are unknown. We postulated that endotoxin elicits specific changes in electron transport chain proteins that produce derangements in mitochondrial function. To examine this issue, we compared the effects of endotoxin-induced sepsis on mitochondrial ATP (adenosine triphosphate) formation and electron transport chain protein composition. Diaphragm mitochondrial oxygen consumption and mitochondrial nicotinamide adenine dinucleotide, reduced form, oxidase assays were measured in control rats (n=13) and rats given endotoxin (8 mg/kg/d) for 12 (n=14), 24 (n=14), 36 (n=14), and 48 h (n=13). Electron transport chain subunits from Complexes I, III, IV, and V were isolated using Blue Native polyacrylamide gel electrophoresis techniques. Endotoxin administration: 1) elicited large reductions in mitochondrial oxygen consumption (e.g., 201+/-3.9 SE natoms O/min/mg for controls and 101+/-4.5 SE natoms O/minutes/mg after 48 h endotoxin, p<0.001), in nicotinamide adenine dinucleotide, reduced form, oxidase activity (p<0.002), and in uncoupled respiration (p<0.001) and 2) induced selective reductions in two subunits of Complex I, three subunits of Complex III, one subunit of Complex IV, and one subunit of Complex V. The time course of depletion of protein subunits mirrored alterations in oxygen consumption. Our data indicate that endotoxin selectively depletes critical components of the electron transport chain that diminishes electron flow, reduces proton pumping and decreases ATP formation.

Frataxin interacts functionally with mitochondrial electron transport chain proteins

Frataxin deficiency is the main cause of Friedreich ataxia, an autosomal recessive neurodegenerative disorder. Frataxin function in mitochondria has not been fully explained yet. In this work, we show that Saccharomyces cerevisiae frataxin orthologue Yfh1p interacts physically with succinate dehydrogenase complex subunits Sdh1p and Sdh2p of the yeast mitochondrial electron transport chain and also with electron transfer flavoprotein complex ETFalpha and ETFbeta subunits from the electron transfer flavoprotein complex. Genetic synthetic interaction experiments confirmed a functional relationship between YFH1 and succinate dehydrogenase genes SDH1 and SDH2. We also demonstrate a physical interaction between human frataxin and human succinate dehydrogenase complex subunits, suggesting also a key role of frataxin in the mitochondrial electron transport chain in humans. Consequently, we suggest a direct participation of the respiratory chain in the pathogenesis of the Friedreich ataxia, which we propose to be considered as an OXPHOS disease.

Differential expression of mitochondrial electron transport chain proteins in cardiac tissues of broilers from pulmonary hypertension syndrome-resistant and -susceptible lines

Pulmonary hypertension syndrome (PHS) is a metabolic disease associated with the rapid growth rate of modern broilers. Broilers susceptible to PHS experience sustained elevation of pulmonary arterial pressure leading to right ventricular hypertrophy and ultimately heart failure. Previous studies have shown that mitochondrial function is defective in broilers with PHS; they use oxygen less efficiently than broilers without PHS. In this study mitochondrial electron transport chain (ETC) protein levels were compared in cardiac tissues from PHS resistant and susceptible line broilers using quantitative immunoblots. Seven of 9 anti-mammalian mitochondrial ETC protein antibodies tested exhibited cross-species reactivity. Six ETC proteins were differentially expressed in the right ventricles of broilers raised under simulated high altitude conditions (2,900 m above sea level). Four ETC proteins were present at higher levels in resistant line birds without PHS than in resistant line birds with PHS or in susceptible line birds with or without PHS. One ETC protein was present at higher levels in broilers without PHS than in broilers with PHS in both lines, and one ETC protein was present at lower levels in susceptible line birds without PHS than in susceptible line birds with PHS or in resistant line birds with or without PHS. Interestingly, differential expression of mitochondrial ETC proteins was not observed in the right ventricles of broilers raised at local altitude (390 m above sea level) nor was it observed in the left ventricles of broilers exposed to simulated high altitude. These results suggest that higher levels of mitochondrial ETC proteins in right ventricle cardiac muscle may be correlated with resistance to PHS in broilers.

Effect of chronic hypoxia on the pulmonary arterial blood pressure of the chicken

Effect of chronic hypoxia on the pulmonary arterial blood pressure of the chicken