Immobilized mitochondrial electron transport particle for NADH determination

Nonphosphorylating electron transport particles (ETP) prepared from beef heart mitochondrion were immobilized in agar gel. The immobilized ETP showed an oxidase activity to both NADH and succinate. The immobilized ETP was reusable. An electrochemical device for the determination of either NADH or succinate was assembled consisting of the membrane-bound ETP and an oxygen probe. The response to succinate was specifically inhibited by the addition of malonate.     

Oxygen tolerance and coupling of mitochondrial electron transport

Oxygen is critical to aerobic metabolism, but excessive oxygen (hyperoxia) causes cell injury and death. An oxygen-tolerant strain of HeLa cells, which proliferates even under 80% O2, termed "HeLa-80," was derived from wild-type HeLa cells ("HeLa-20") by selection for resistance to stepwise increases of oxygen partial pressure. Surprisingly, antioxidant defenses and susceptibility to oxidant-mediated killing do not differ between these two strains of HeLa cells. However, under both 20 and 80% O2, intracellular reactive oxygen species (ROS) production is significantly (approximately 2-fold) less in HeLa-80 cells. In both cell lines the source of ROS is evidently mitochondrial. Although HeLa-80 cells consume oxygen at the same rate as HeLa-20 cells, they consume less glucose and produce less lactic acid. Most importantly, the oxygen-tolerant HeLa-80 cells have significantly higher cytochrome c oxidase activity (approximately 2-fold), which may act to deplete upstream electron-rich intermediates responsible for ROS generation. Indeed, preferential inhibition of cytochrome c oxidase by treatment with n-methyl protoporphyrin (which selectively diminishes synthesis of heme a in cytochrome c oxidase) enhances ROS production and abrogates the oxygen tolerance of the HeLa-80 cells. Thus, it appears that the remarkable oxygen tolerance of these cells derives from tighter coupling of the electron transport chain.     

Structure of the mitochondrial ATP synthase by electron cryomicroscopy

We have determined the structure of intact ATP synthase from bovine heart mitochondria by electron cryomicroscopy of single particles. Docking of an atomic model of the F1-c10 subcomplex into a major segment of the map has allowed the 32 A resolution density to be interpreted as the F1-ATPase, a central and a peripheral stalk and an FO membrane region that is composed of two domains. One domain of FO corresponds to the ring of c-subunits, and the other probably contains the a-subunit, the transmembrane portion of the b-subunit and the remaining integral membrane proteins of FO. The peripheral stalk wraps around the molecule and connects the apex of F1 to the second domain of FO. The interaction of the peripheral stalk with F1-c10 implies that it binds to a non-catalytic alpha-beta interface in F1 and its inclination where it is not attached to F1 suggests that it has a flexible region that can serve as a stator during both ATP synthesis and ATP hydrolysis.     

Mobility in the mitochondrial electron transport chain

The role of lateral diffusion in mitochondrial electron transport has been investigated by measuring the diffusion coefficients for lipid, cytochrome c, and cytochrome oxidase in membranes of giant mitoplasts from cuprizone-fed mice using the technique of fluorescence redistribution after photobleaching (FRAP). The diffusion coefficient of the phospholipid analogue N-(7-nitro-2,1,3-benzoxadiazol-4-yl)phosphatidylethanolamine is dependent on the technique used to remove the outer mitochondrial membrane. A sonication technique yields mitoplasts with monophasic recovery of the lipid probe (D = 6 X 10(-9) cm2/s), while digitonin-treated mitochondria show biphasic recoveries (D1 = 5 X 10(-9) cm2/s; D2 = 1 X 10(-9) cm2/s). Digitonin appears to incorporate into mitoplasts, giving rise to decreased lipid mobility concomitant with increased rates of electron transfer from succinate to oxygen, in a manner reminiscent of the effects of cholesterol incorporation [Schneider, H., Lemasters, J. J., Hochli, M., & Hackenbrock, C. R. (1980) J. Biol. Chem. 255, 3748-3756]. FRAP measurements on tetramethylrhodamine cytochrome c modified at lysine-39 and on a mixture of active morpholinorhodamine derivatives of cytochrome c gave diffusion coefficients of (3.5-7) X 10(-10) cm2/s depending on the assay medium. With morpholinorhodamine-labeled antibodies purified on a cytochrome oxidase affinity column, the diffusion coefficient for cytochrome oxidase was determined to be 1.5 X 10(-10) cm2/s. The results are discussed in terms of a dynamic aggregate model in which an equilibrium exists between freely diffusing and associated electron-transfer components.     

Variation among Plasmodium falciparum strains in their reliance on mitochondrial electron transport chain function

Previous studies demonstrated that Plasmodium falciparum strain D10 became highly resistant to the mitochondrial electron transport chain (mtETC) inhibitor atovaquone when the mtETC was decoupled from the pyrimidine biosynthesis pathway by expressing the fumarate-dependent (ubiquinone-independent) yeast dihydroorotate dehydrogenase (yDHODH) in parasites. To investigate the requirement for decoupled mtETC activity in P. falciparum with different genetic backgrounds, we integrated a single copy of the yDHODH gene into the genomes of D10attB, 3D7attB, Dd2attB, and HB3attB strains of the parasite. The yDHODH gene was equally expressed in all of the transgenic lines. All four yDHODH transgenic lines showed strong resistance to atovaquone in standard short-term growth inhibition assays. During longer term growth with atovaquone, D10attB-yDHODH and 3D7attB-yDHODH parasites remained fully resistant, but Dd2attB-yDHODH and HB3attB-yDHODH parasites lost their tolerance to the drug after 3 to 4 days of exposure. No differences were found, however, in growth responses among all of these strains to the Plasmodium-specific DHODH inhibitor DSM1 in either short- or long-term exposures. Thus, DSM1 works well as a selective agent in all parasite lines transfected with the yDHODH gene, whereas atovaquone works for some lines. We found that the ubiquinone analog decylubiquinone substantially reversed the atovaquone inhibition of Dd2attB-yDHODH and HB3attB-yDHODH transgenic parasites during extended growth. Thus, we conclude that there are strain-specific differences in the requirement for mtETC activity among P. falciparum strains, suggesting that, in erythrocytic stages of the parasite, ubiquinone-dependent dehydrogenase activities other than those of DHODH are dispensable in some strains but are essential in others.     

Quantitative relationship between photosystem I electron transport and ATP formation

The Photosystem I-dependent transport of electrons from diaminodurene to methylviologen is linear with reaction time and supports a constant rate of phosphorylation. However, if the diaminodurene is not kept fully reduced by the presence of excess ascorbate, the oxidized diaminodurene accumulates and begins to compete with the methylviologen as the electron acceptor. Thus, although the rate of ATP formation remains unchanged, an increasing proportion of the electron transport becomes cyclic and hence unmeasured. This leads to a rapid increase in the apparent efficiency of phosphorylation which is misleading.In contrast, it is known that the oxidized form of 3,3′-diaminobenzidine polymerizes to form an insoluble substance which should not be available to serve as an electron acceptor. However, 3,3′-diaminobenzidine is not a satisfactory donor of electrons in Photosystem I reactions for two reasons: the rate of electron transport quickly falls with reaction time and the oxidized form of 3,3′-diaminobenzidine seems to be an exceptionally efficient electron acceptor near the beginning of the period of illumination when it is presumably not yet polymerized. Thus in the first 2–3 sec of illumination when the reaction is still rapid much of the electron transport is cyclic and therefore unmeasured, especially in the absence of excess ascorbate. This cycling of electrons, which leads to an inflated apparent efficiency ($\text{P}\text{e}{}_2\text{> 2}$), is particularly pronounced at low donor concentrations.When cyclic electron transport is avoided by the use of ascorbate or by the selection of appropriate reaction times, both diaminodurene and 3,3′-diaminobenzidine support phosphorylation with an efficiency which is approximately half of the efficiency exhibited by the overall Hill reaction. The same is true when 2,5-diaminotoluene, tetrachlorohydroquinone, 4,5-dimethyl-o-phenylenediamine, and reduced 2,6-dichloroindophenol serve as electron donors. With these six substances, the phosphorylation efficiences were 0.57 ± 0.1 molecules of ATP formed for each pair of electrons transferred ($\text{P}\text{e}{}_2$). In the same chloroplasts preparations, the transport of electrons from water to methylviologen-supported phosphorylation with a $\text{P}\text{e}{}_2$ of 1.2.     

Stabilization by glutaraldehyde of high-rate electron transport in isolated chloroplasts

Treatment of isolated chloroplasts with glutaraldehyde affects their ability to photoreduce artificial electron acceptors. The remaining rate of O₂ evolution approaches zero with methyl viologen, is low with ferricyanide, but nearly normal with lipophilic Photosystem II acceptors, like oxidized p-phenylenediamine and oxidized diaminodurene. Since Photosystem I donor reactions are also affected, a specific site of inhibition of electron transport to Photosystem I is indicated. At the same time, glutaraldehyde prolongs the longevity of the chloroplasts stored in dark. In control samples the half-life of Photosystem II activity varied between 5 days at 4 °C and 1 day at 25 °C. Glutaraldehyde treatment increased these half times approx. 3-fold. The glutaraldehyde doses required to induce inhibition and stabilization were very similar.     

The role of mitochondrial electron transport in tumorigenesis and metastasis

Background

Tumor formation and spread via the circulatory and lymphatic drainage systems is associated with metabolic reprogramming that often includes increased glycolytic metabolism relative to mitochondrial energy production. However, cells within a tumor are not identical due to genetic change, clonal evolution and layers of epigenetic reprogramming. In addition, cell hierarchy impinges on metabolic status while tumor cell phenotype and metabolic status will be influenced by the local microenvironment including stromal cells, developing blood and lymphatic vessels and innate and adaptive immune cells. Mitochondrial mutations and changes in mitochondrial electron transport contribute to metabolic remodeling in cancer in ways that are poorly understood.

Scope of Review

This review concerns the role of mitochondria, mitochondrial mutations and mitochondrial electron transport function in tumorigenesis and metastasis.

Major Conclusions

It is concluded that mitochondrial electron transport is required for tumor initiation, growth and metastasis. Nevertheless, defects in mitochondrial electron transport that compromise mitochondrial energy metabolism can contribute to tumor formation and spread. These apparently contradictory phenomena can be reconciled by cells in individual tumors in a particular environment adapting dynamically to optimally balance mitochondrial genome changes and bioenergetic status.

General Significance

Tumors are complex evolving biological systems characterized by genetic and adaptive epigenetic changes. Understanding the complexity of these changes in terms of bioenergetics and metabolic changes will permit the development of better combination anticancer therapies. This article is part of a Special Issue entitled Frontiers of Mitochondrial Research.     

Uptake of ATP analogs by isolated pea chloroplasts and their effect on CO2 fixation and electron transport.

1. The ATP analog, adenylyl-imidodiphosphate rapidly inhibited CO2-dependent oxygen evolution by isolated pea chloroplasts. Both alpha, beta- and beta, gamma-methylene adenosine triphosphate also inhibited oxygen evolution. The inhibition was relieved by ATP but only partially relieved by 3-phosphoglycerate. Oxygen evolution with 3-phosphoglycerate as substrate was inhibited by adenylyl-imidodiphosphate to a lesser extent than CO2-dependent oxygen evolution. The concentration of adenylylimidodiphosphate required for 50% inhibition of CO2-dependent oxygen evolution was 50 micronM. 2. Although non-cyclic photophosphorylation by broken chloroplasts was not significantly affected by adenylyl-imidodiphosphate, electron transport in the absence of ADP was inhibited by adenylyl-imidodiphosphate to the same extent as by ATP, suggesting binding of the ATP analog to the coupling factor of phosphorylation. 3. The endogenous adenine nucleotides of a chloroplast suspension were labelled by incubation with [14C]ATP and subsequent washing. Addition of adenylyl-imidodiphosphate to the labelled chloroplasts resulted in a rapid efflux of adenine nucleotides suggesting that the ATP analog was transported into the chloroplasts via the adenine nucleotide translocator. 4. It was concluded that uptake of ATP analogs in exchange for endogenous adenine nucleotides decreased the internal ATP concentration and thus inhibited CO2 fixation. Oxygen evolution was inhibited to a lesser extent in spinach chloroplasts which apparently have lower rates of adenine nucleotide transport than pea chloroplasts.     

Evidence for chemiosmotic coupling of electron transport to ATP synthesis in spinach chloroplasts

In spinach chloroplasts it has been shown that (1) the size of the proton gradient under phosphorylating conditions is smaller than under non-phosphorylating conditions; (2) ADP, ATP or Dio-9, added under non-phosphorylating conditions, decrease the rate of electron transport but increase the size of the proton gradient; (3) ADP, ATP or Dio-9 inhibit not only electron transport but also the rate of decay of the proton gradient; (4) the H⁺/e⁻ ratio under non-phosphorylating conditions is 1.0. It is not affected by ADP, ATP or Dio-9.

These results show that protons pass out of the thylakoids at the site of ATP synthesis and that this leakage is inhibited by ADP, ATP or Dio-9, compounds that interact with the site of ATP synthesis. As these compounds do not alter the H⁺/e⁻ ratio the formation of the proton gradient must be an intermediate between electron transport and ATP synthesis. These data are in support of the chemiosmotic theory of coupling of electron transport to ATP synthesis.     

Oxidatively damaged proteins of heart mitochondrial electron transport complexes

Protein modifications, such as carbonylation, nitration and formation of lipid peroxidation adducts, e.g. 4-hydroxynonenal (HNE), are products of oxidative damage attributed to reactive oxygen species (ROS). The mitochondrial respiratory chain Complexes I and III have been shown to be a major source of ROS in vitro. Additionally, modifications of the respiratory chain Complexes (I-V) by nitration, carbonylation and HNE adduct decrease their enzymatic activity in vitro. However, modification of these respiratory chain complex proteins due to in vivo basal level ROS generation has not been investigated. In this study, we show a basal level of oxidative damage to specific proteins of adult bovine heart submitochondrial particle (SMP) complexes, and find that most of these proteins are localized in the mitochondrial matrix. We postulate that electron leakage from respiratory chain complexes and subsequent ROS formation may cause damage to specific complex subunits and contribute to long-term accumulation of mitochondrial dysfunction.     

The role of Coenzyme Q in mitochondrial electron transport

In mitochondria, most Coenzyme Q is free in the lipid bilayer; the question as to whether tightly bound, non-exchangeable Coenzyme Q molecules exist in mitochondrial complexes is still an open question.We review the mechanism of inter-complex electron transfer mediated by ubiquinone and discuss the kinetic consequences of the supramolecular organization of the respiratory complexes (randomly dispersed vs. super-complexes) in terms of Coenzyme Q pool behavior vs. metabolic channeling, respectively, both in physiological and in some pathological conditions. As an example of intra-complex electron transfer, we discuss in particular Complex I, a topic that is still under active investigation.     

Isolating the segment of the mitochondrial electron transport chain responsible for mitochondrial damage during cardiac ischemia

Ischemia damages the mitochondrial electron transport chain (ETC), mediated in part by damage generated by the mitochondria themselves. Mitochondrial damage resulting from ischemia, in turn, leads to cardiac injury during reperfusion. The goal of the present study was to localize the segment of the ETC that produces the ischemic mitochondrial damage. We tested if blockade of the proximal ETC at complex I differed from blockade distal in the chain at cytochrome oxidase. Isolated rabbit hearts were perfused for 15 min followed by 30 min stop-flow ischemia at 37 °C. Amobarbital (2.5 mM) or azide (5 mM) was used to block proximal (complex I) or distal (cytochrome oxidase) sites in the ETC. Time control hearts were buffer-perfused for 45 min. Subsarcolemmal mitochondria (SSM) and interfibrillar mitochondria (IFM) were isolated. Ischemia decreased cytochrome c content in SSM but not in IFM compared to time control. Blockade of electron transport at complex I preserved the cytochrome c content in SSM. In contrast, blockade of electron transport at cytochrome oxidase with azide did not retain cytochrome c in SSM during ischemia. Since blockade of electron transport at complex III also prevented cytochrome c loss during ischemia, the specific site that elicits mitochondrial damage during ischemia is likely located in the segment between complex III and cytochrome oxidase.