Peculiarities of functioning of wheat cut-off root cells at inhibition of complexes I and II of mitochondrial respiratory chain

Combined action of rotenone and malonate, inhibitors of complexes I and II of the mitochondrial electron transport chain (ETC), on wheat cut-off root seedlings was studied after 6 h of incubation. Intensity of oxygen consumption and release of potassium ions into incubation medium were determined simultaneously with the study of changes in cell ultrastructure. Malonic acid was added 1 h after the root incubation in the rotenone solution and produced inhibition of respiration, as well as a greater release of K⁺ into the incubation solution as compared with effect of rotenone alone. After 2 h of the combined action of these inhibitors, many mitochondria acquired a toroidal shape, thereby increasing the outer surface. For the ensuing hours, stimulation of oxygen consumption by the roots and a decrease of K⁺ content in the incubation medium were observed. Mitochondria once again acquired a round or oval shape and compensation-reparation processes took place. Contacts of endoplasmic reticulum channels with mitochondria were observed, which seems to be due to the synthesis of the enzyme splitting malonate to acetyl-CoA, which in turn can be included both into the Krebs cycle and into lipogenesis. It is suggested that the toroidal form of mitochondria is associated with the activation of the external NAD(P)H-dehydrogenase of the inner mitochondrial membrane, as under these conditions, at the inhibition of the ETC complexes I and II, the activity of other dehydrogenises is blocked. Thus, the use of the external NAD(P)H allows the activity of the ETC mitochondria to be restored, which facilitates the course of the reparation processes and allows cells to be adapted to this action.     

Ambivalent effects of diazoxide on mitochondrial ROS production at respiratory chain complexes I and III

Background

Reactive oxygen species (ROS) are among the main determinants of cellular damage during ischemia and reperfusion. There is also ample evidence that mitochondrial ROS production is involved in signaling during ischemic and pharmacological preconditioning. In a previous study we analyzed the mitochondrial effects of the efficient preconditioning drug diazoxide and found that it increased the mitochondrial oxidation of the ROS-sensitive fluorescent dye 2′,7′-dichlorodihydrofluorescein (H₂DCF) but had no direct impact on the H₂O₂ production of submitochondrial particles (SMP) or intact rat heart mitochondria (RHM).

Methods

H₂O₂ generation of bovine SMP and tightly coupled RHM was monitored under different conditions using the amplex red/horseradish peroxidase assay in response to diazoxide and a number of inhibitors.

Results

We show that diazoxide reduces ROS production by mitochondrial complex I under conditions of reverse electron transfer in tightly coupled RHM, but stimulates mitochondrial ROS production at the Q_o site of complex III under conditions of oxidant-induced reduction; this stimulation is greatly enhanced by uncoupling. These opposing effects can both be explained by inhibition of complex II by diazoxide. 5-Hydroxydecanoate had no effect, and the results were essentially identical in the presence of Na⁺ or K⁺ excluding a role for putative mitochondrial K_ATP-channels.

General significance

A straightforward rationale is presented to mechanistically explain the ambivalent effects of diazoxide reported in the literature. Depending on the metabolic state and the membrane potential of mitochondria, diazoxide-mediated inhibition of complex II promotes transient generation of signaling ROS at complex III (during preconditioning) or attenuates the production of deleterious ROS at complex I (during ischemia and reperfusion).     

Decylubiquinol impedes mitochondrial respiratory chain complex I activity

In this study, indirect immunofluorescence labeling was used to examine the cellular dynamic distribution of Thr11 phosphorylated H3 at mitosis in MCF-7 cells. The Thr11 phosphorylation was observed beginning at prophase at centromeres. Upon progression of mitosis, fluorescence signal was enhanced in the central region of the metaphase plate and maintained till anaphase at centromeres. During telophase, the fluorescent signal of Thr11 phosphorylated H3 disappears from centromeres, but the signal appears again at the midbody during cytokinesis, which suggests that the modified histones may take part in the formation of the midbody and play a crucial role in cytokinesis. Chromatin immunoprecipitation (ChIP) was used to confirm that Thr11 phosphorylated H3 is specifically associated with centromere DNA at prophase to metaphase, which is coincident with the results observed by immunofluorescence. In conclusion, there was a precise spatial and temporal correlation between H3 phosphorylation of Thr11 and stages of chromatin condensation. The timing of Thr11 phosphorylation and dephosphorylation in mitosis were similar to that reported for Ser10 phosphorylation of H3. The Thr11 phosphorylated H3 localized at centromeres during mitosis, which was different from the Ser10 phosphorylated H3 localized at telomere regions and Thr3 phosphorylated H3 localized along the chromosome arms. The results suggest that the Thr11 phosphorylation of histone H3 may play a specific role which was different from Ser10 and Thr3 phosphorylation in mitosis.     

A molecular link between mitochondrial preprotein transporters and respiratory chain complexes

The TIM17:23 complex on the mitochondrial inner membrane is responsible for import of the majority of mitochondrial proteins in plants. In Arabidopsis, Tim17 and Tim23 belong to a large gene family consisting of 16 members termed the Preprotein and Amino acid transporters (PRAT). Recently, two members of this protein family, Tim23-2 and the Complex I subunit B14.7, have been shown to assemble into both Complex I of the respiratory chain and the TIM17:23 complex (Wang et al., 2012), adding to other examples of links between respiratory and protein import complexes. These associations provide a mechanism to coordinate mitochondrial activity and biogenesis.     

Electrophysiology of respiratory chain complexes and the ADP-ATP exchanger in native mitochondrial membranes

Transport of protons and solutes across mitochondrial membranes is essential for many physiological processes. However, neither the proton-pumping respiratory chain complexes nor the mitochondrial secondary active solute transport proteins have been characterized electrophysiologically in their native environment. In this study, solid-supported membrane (SSM) technology was applied for electrical measurements of respiratory chain complexes CI, CII, CIII, and CIV, the F(O)F(1)-ATPase/synthase (CV), and the adenine nucleotide translocase (ANT) in inner membranes of pig heart mitochondria. Specific substrates and inhibitors were used to validate the different assays, and the corresponding K(0.5) and IC(50) values were in good agreement with previously published results obtained with other methods. In combined measurements of CI-CV, it was possible to detect oxidative phosphorylation (OXPHOS), to measure differential effects of the uncoupler carbonyl cyanide m-chlorophenylhydrazone (CCCP) on the respective protein activities, and to determine the corresponding IC(50) values. Moreover, the measurements revealed a tight functional coupling of CI and CIII. Coenzyme Q (CoQ) analogues decylubiquinone (DBQ) and idebenone (Ide) stimulated the CII- and CIII-specific electrical currents but had inverse effects on CI-CIII activity. In summary, the results describe the electrophysiological and pharmacological properties of respiratory chain complexes, OXPHOS, and ANT in native mitochondrial membranes and demonstrate that SSM-based electrophysiology provides new insights into a complex molecular mechanism of the respiratory chain and the associated transport proteins. Besides, the SSM-based approach is suited for highly sensitive and specific testing of diverse respiratory chain modulators such as inhibitors, CoQ analogues, and uncoupling agents.     

Structural and functional organization of Complex I in the mitochondrial respiratory chain

Metabolic flux control analysis of NADH oxidation in bovine heart submitochondrial particles revealed high flux control coefficients for both Complex I and Complex III, suggesting that the two enzymes are functionally associated as a single enzyme, with channelling of the common substrate, Coenzyme Q. This is in contrast with the more accepted view of a mobile diffusable Coenzyme Q pool between these enzymes. Dilution with phospholipids of a mitochondrial fraction enriched in Complexes I and III, with consequent increased theoretical distance between complexes, determines adherence to pool behavior for Coenzyme Q, but only at dilution higher than 1:5 (protein:phospholipids), whereas, at lower phospholipid content, the turnover of NADH cytochrome c reductase is higher than expected by the pool equation.     

Tissue specific defect of complex I of the mitochondrial respiratory chain

Deficiency of complex I is one of the most commonly reported defects of the mitochondrial respiratory chain in man. Clinical evidence of tissue specific expression of complex I deficiency has not previously been confirmed biochemically. We report here slow oxidation of NAD+-linked substrates, low activity of complex I and low amounts of immunoreactive complex I peptides in skeletal muscle mitochondria from a patient with muscle weakness and lactic acidosis. In liver mitochondria complex I activity was normal and all the immunoreactive subunits of complex I were present in normal amounts.     

Age-related changes in the activities of respiratory chain complexes and mitochondrial morphology in Drosophila

Using Drosophila melanogaster, we examined changes in the activities of some of the respiratory enzyme complexes with age. The age-related decreases of enzyme activities were observed especially in complex I. We also examined changes in the ultrastructure of mitochondria in the flight muscles of thoraces. The results indicated that the mitochondrial size varied more widely in aged flies than in young ones, in addition to the slight increase in the average size with age. These changes had already appeared before the survival began to decrease, clearly indicating that the accumulation of such changes seriously damages mitochondrial function.     

Inactivation of mitochondrial respiratory chain complex I leads mitochondrial nitric oxide synthase to become pro-oxidative

We recently demonstrated that mitochondrial nitric oxide synthase (mtNOS) functionally couples with mitochondrial respiratory chain complex I to produce nitric oxide [M.S. Parihar, R.R. Nazarewicz, E. Kincaid, U. Bringold, P. Ghafourifar, Association of mitochondrial nitric oxide synthase activity with respiratory chain complex I, Biochem. Biophys. Res. Commun. 366 (2008) 23-28] [1]. The present report shows that inactivation of complex I leads mtNOS to become pro-oxidative. Our findings suggest a crucial role for mtNOS in oxidative stress caused by mitochondrial complex I inactivation.     

Assessment of mitochondrial respiratory chain enzymatic activities on tissues and cultured cells

The assessment of mitochondrial respiratory chain (RC) enzymatic activities is essential for investigating mitochondrial function in several situations, including mitochondrial disorders, diabetes, cancer, aging and neurodegeneration, as well as for many toxicological assays. Muscle is the most commonly analyzed tissue because of its high metabolic rates and accessibility, although other tissues and cultured cell lines can be used. We describe a step-by-step protocol for a simple and reliable assessment of the RC enzymatic function (complexes I-IV) for minute quantities of muscle, cultured cells and isolated mitochondria from a variety of species and tissues, by using a single-wavelength spectrophotometer. An efficient tissue disruption and the choice for each assay of specific buffers, substrates, adjuvants and detergents in a narrow concentration range allow maximal sensitivity, specificity and linearity of the kinetics. This protocol can be completed in 3 h.     

Association of mitochondrial nitric oxide synthase activity with respiratory chain complex I

The present study shows that rat liver and brain mitochondrial nitric oxide synthase (mtNOS) are functionally associated with mitochondrial respiratory chain complex I. When complex I is activated, mtNOS exerts high activity and generates nitric oxide, whereas inactivation of complex I leads mtNOS to abandon its NOS activity. Functional association of mtNOS with complex I is potentially important in regulating mtNOS activity and mitochondrial functions.     

Respiration of wheat root cells under simultaneous inhibition of parts I and III of the electron transport chain of mitochondria by rotenone and antimycine A

Respiration of excised roots of 5 day old wheat seedlings with blocked mitochondrial oxidation under simultaneous action of rotenone and antimycine A was studied. A reduced rate of oxygen uptake was observed within the first hour of root treatment inhibitors. However, after a 5 h exposure there was an increase in oxygen uptake, which was prevented by KCN but amplified by malate and ascorbate. The application of inhibitors caused a considerable increase in the respiratory coefficient (RC) up to 2.1, that suggests a significant CO2 release, when the initial sites of mitochondrial electron transport chain were inhibited. RC did not raise, when ascorbate was added in the presence of inhibitors. We assume that inhibition of mitochondrial oxidation at I and III sites of electron transport chain facilitates switching on the alternative paths of reductant translocation to oxygen. Participation of ATPases and redox system of plasma membrane in the response reactions of respiration directed to the restoration of ion, particularly, proton homeostasis in conditions of inhibited mitochondrial oxidation is discussed.     

Enhancement of human embryonic stem cell pluripotency through inhibition of the mitochondrial respiratory chain

Human embryonic stem cell (hESC) pluripotency has been reported by several groups to be best maintained by culture under physiological oxygen conditions. Building on that finding, we inhibited complex III of the mitochondrial respiratory chain using antimycin A or myxothiazol to examine if specifically targeting the mitochondria would have a similar beneficial result for the maintenance of pluripotency. hESCs grown in the presence of 20 nM antimycin A maintained a compact morphology with high nuclear/cytoplasmic ratios. Furthermore, real-time PCR analysis demonstrated that the levels of Nanog mRNA were elevated 2-fold in antimycin A-treated cells. Strikingly, antimycin A was also able to replace bFGF in the media without compromising pluripotency, as long as autocrine bFGF signaling was maintained. Further analysis using low-density quantitative PCR arrays showed that antimycin A treatment reduced the expression of genes associated with differentiation, possibly acting through a ROS-mediated pathway. These results demonstrate that modulation of mitochondrial function results in increased pluripotency of the cell population, and sheds new light on the mechanisms and signaling pathways modulating hESC pluripotency.     

Assay of mitochondrial respiratory chain complex I in human lymphocytes and cultured skin fibroblasts

Respiratory chain complex I (NADH:ubiquinone oxidoreductase) deficiency is one of the most frequent causes of mitochondrial disease in humans. The activity of this complex can be confidently measured in most tissue samples, but not in cultured skin fibroblasts or circulating lymphocytes. Highly contaminating non-mitochondrial NADH-quinone oxidoreductase activity in fibroblasts and the limited access of substrates to complex I in lymphocytes hinder its measurement in permeabilized cells. Complex I assay in these cells requires the isolation of mitochondria, which in turn necessitates large quantities of cells and is not feasible when studying circulating lymphocytes. Here we report a simple method to measure complex I activity in a minute amount of either cell type. The procedure strongly reduces contaminating NADH:quinone oxidoreductase activity and permits measuring high rates of rotenone-sensitive complex I activity thanks to effective cell permeabilization.     

Tracing the trail of protons through complex I of the mitochondrial respiratory chain

Mitochondria are the structures that produce the bulk part of the cellular energy currency ATP, which drives numerous energy requiring processes in the cell. This process involves a series of large enzyme complexes--the respiratory chain--that couples the transfer of electrons to the creation of a concentration gradient of protons across the inner mitochondrial membrane, which drives ATP synthesis. Complex I (or NADH-quinone oxidoreductase) is the largest and by far the most complicated of the respiratory chain enzyme complexes. The molecular mechanism whereby it couples electron transfer to proton extrusion has remained mysterious until very recently. Low-resolution X-ray structures of complex I have, surprisingly, suggested that electron transfer in the hydrophilic arm, protruding into the mitochondrial matrix, causes movement of a coupling rod that influences three putative proton pumps within the hydrophobic arm embedded in the inner mitochondrial membrane. In this Primer, we will briefly introduce the recent progress made in this area and highlight the road ahead that likely will unravel the detailed molecular mechanisms of complex I function.