Isolation of mitochondria from ascites tumor cells permeabilized with digitonin

A new, improved procedure for isolating mitochondria from ascites tumor cells is described. The unique feature of this technique is the use of digitonin to make the cells susceptible to disruption by Teflon pestle/glass vessel homogenization. The yield and respiratory control ratios of mitochondria isolated by this method from murine Ehrlich ascites tumor cells and rat AS30-D ascites hepatoma cells are significantly better than those obtained for mitochondria isolated by the commonly employed Nagarse method, which involves the use of proteolytic enzymes. Moreover, mitochondria isolated by this new procedure from three different lines of tumors exhibit respiratory control ratios with both adenosine diphosphate and a respiratory uncoupler comparable to those obtained with mitochondria present in situ within digitonin-permeabilized tumor cells.     

Mitochondrial respiratory activity of the trematode Fasciola hepatica

Polarographic studies have been made on the respiratory activity of isolated mitochondria of the trematode F. hepatica. Respiratory chain transferring electrons to oxygen and which is sensitive to cyanide was found in the mitochondria. Certain coupling between respiration and phosphorylation was observed. Intact mitochondria of the trematode exhibit the respiratory control although its level is significantly lower than that in the mitochondria from rat liver. The existence of an alternative respiratory chain was demonstrated in which electron transport is not associated with ATP synthesis.     

The presence of the glycerol phosphate shuttle and energy dependent transhydrogenase in aortic mitochondria

A procedure has been devised for isolating tightly coupled mitochondria from the intima-media strip of pig aorta. The mitochondria exhibit respiratory control with succinate, pyruvate-malate, β-hydroxybutyrate or α-glycerol phosphate as substrate. Furthermore, submitochondrial particles from these preparations exhibit an energy-dependent reduction of NADP⁺ by NADH.     

Heart and breast muscle mitochondrial dysfunction in pulmonary hypertension syndrome in broilers (Gallus domesticus)

This study was conducted to determine function and defects in electron transport in muscle mitochondria of meat chickens (broilers) with pulmonary hypertension syndrome (PHS). The respiratory control ratio (RCR, indicative of respiratory chain coupling) was higher in the control than in PHS breast and heart muscle mitochondria, but there were no differences in the ADP/O (an index of oxidative phosphorylation). Sequential additions of ADP improved the RCR in the control breast muscle mitochondria and the ADP/O in PHS breast and heart muscle mitochondria. Basal hydrogen peroxide production, (an indicator of electron leak), was higher in PHS breast and heart muscle mitochondria than in controls and differences in electron leak in PHS mitochondria were magnified by inhibiting electron transport at Complex I and III (cyt b(562)). Complex I activity was lower in PHS heart mitochondria but there was no difference in Complex II activity. Thus, compared to controls, PHS mitochondria exhibited site-specific defects in electron transport within Complex I and III that could contribute to lower respiratory chain coupling. Additionally, it appears that healthy broilers may exhibit higher basal levels of electron leak compared to other avian species. Together, these findings provide insight into inefficient cellular use of oxygen that may contribute to the development of PHS in broilers.     

Mitochondrial dysfunction in Huntington's disease: the bioenergetics of isolated and in situ mitochondria from transgenic mice

Mitochondrial dysfunction is believed to participate in Huntington's disease (HD) pathogenesis. Here we compare the bioenergetic behavior of forebrain mitochondria isolated from different transgenic HD mice (R6/2, YAC128 and Hdh150 knock-in) and wild-type littermates with the first determination of in situ respiratory parameters in intact HD striatal neurons. We assess the Ca2+-loading capacity of isolated mitochondria by steady Ca2+-infusion. Mitochondria from R6/2 mice (12-13 weeks) and 12 months YAC128, but not homozygous or heterozygous Hdh150 knock-in mice (15-17 weeks), exhibit increased Ca2+-loading capacity when compared with respective wild-type littermates. In situ mitochondria in intact striatal neurons show high respiratory control. Moreover, moderate expression of full-length mutant huntingtin (in Hdh150 knock-in heterozygotes) does not significantly impair mitochondrial respiration in unstimulated neurons. However, when challenged with energy-demanding stimuli (NMDA-receptor activation in pyruvate-based media to accentuate the mitochondria role in Ca2+-handling), Hdh150 neurons are more vulnerable to Ca2+-deregulation than neurons from their wild-type littermates. These results stress the importance of assessing HD mitochondrial function in the cellular context.     

Properties of mitochondria isolated from cyanide-sensitive and cyanide-stimulated cultures of Acanthamoeba castellanii

1. Mitochondria isolated from cultures of Acanthamoeba castellanii exhibit respiratory control and oxidize alpha-oxoglutarate, succinate and NADH with ADP:O ratios of about 2.4, 1.4 and 1.25 respectively. 2. Mitochondria from cultures of which the respiration was stimulated up to 50% by 1mm-cyanide (type-A mitochondria) and from cyanide-sensitive cultures (type-B mitochondria) had similar respiratory-control ratios and ADP:O ratios. 3. State-3 rates of respiration were generally more cyanide-sensitive than State-4 rates, and the respiration of type-A mitochondria was more cyanide-resistant than that of type-B mitochondria. 4. Salicylhydroxamic acid alone had little effect on respiratory activities of either type of mitochondria, but when added together with cyanide, irrespective of the order of addition, inhibition was almost complete. 5. Oxidation of externally added NADH by type-A mitochondria was mainly via an oxidase with a low affinity for oxygen (K(m)[unk]15mum), which was largely cyanide-sensitive and partially antimycin A-sensitive; this electron-transport pathway was inhibited by ADP. 6. Cyanide-insensitive but salicylhydroxamic acid-sensitive respiration was stimulated by AMP and ADP, and by ATP after incubation in the presence of MgCl(2). 7. Addition of rotenone to mitochondria oxidizing alpha-oxoglutarate lowered the ADP:O ratios by about one-third and rendered inhibition by cyanide more complete. 8. The results suggest that mitochondria of A. castellanii possess branched pathways of electron transport which terminate in three separate oxidases; the proportions of electron fluxes via these pathways vary at different stages of growth.     

Vitamin E deficiency in the rat. IV. Alteration in mitochondrial membrane and its relation to respiratory decline

The respiratory control and rate of oxidation of exogenous NADH in vitro by liver mitochondria from vitamin E deficient rats were studied as a means of providing information concerning possible mitochondrial membrane alterations due to the deficiency.When mitochondria were aged at different temperatures for various periods of time, half-maximal inhibition of respiratory control occurred at lower temperatures and shorter aging periods in deficient mitochondria than in normal ones. Also, respiratory control was lost more rapidly in deficient mitochondria than in normal ones in the presence of either digitonin or low (hypotonic) concentrations of mannitol.Microsomes, both freshly prepared and boiled, dramatically lowered respiratory control and the effect was greater in the deficient mitochondria. Bovine serum albumin overcame the suppressed respiratory control, and exogenously added fatty acids mimiced the action of the microsomes.NADH oxidation by normal mitochondria proceeded slowly in isotonic media, while mitochondria of vitamin E deficient rats oxidized NADH much more rapidly. When mitochondria were subjected to ultrasonic disruption or incubated in hypotonic media, the rates of NADH oxidation by both types of mitochondria were similar.Respiratory decline associated with oxidation of β-hydroxybutyrate by the deficient mitochondria was decreased by including in the medium either a high concentration of NAD⁺, 0.5 mm oxalacetate, or 2 mm aspartate plus 1 mm α-ketoglutarate. This observation, plus the finding of similar activities of malate dehydrogenase and glutamic-oxalacetic transminase in normal and deficient livers, suggests that the action of each was due to an elevation of the mitochondrial NAD⁺/NADH ratio via a malate shuttle and cytoplasmic and mitochondrial glutamic-oxalacetate transaminase. It is postulated that the marked mitochondrial respiratory decline in the deficient rats is attributed to a limiting availability of NAD⁺ and a low ratio of NAD⁺ to NADH.     

Effect of filipin on Rat-liver and yeast mitochondria

1. Under the appropriate conditions intact yeast and mammalian mitochondria exhibit a heretofore unobserved sensitivity to the polyene antibiotic, filipin. The activity of the “filipin complex” (Filipins I, II, III and IV) is shown to be primarily due to the component designated Filipin II.

2. Yeast mitochondria treated with filipin complex, or purified Filipin II, exhibit “uncoupled” succinate oxidation and inhibited -ketoglutarate oxidation. Maximum filipin effect is observed at a concentration of 4 mM Filipin II. Rat-liver mitochondria are more sensitive to filipin than yeast mitochondria, and respiratory inhibition is observed regardless of substrate.

3. In liver mitochondria filipin-inhibited respiration is not relieved by Mg²⁺, K⁺, Ca²⁺ or 2,4-dinitrophenol, but is reversed by cytochrome c.

4. It is proposed that filipin treatment leads to altered membrane permeability and that respiratory inhibition is due to a loss of endogenous respiratory cofactors or an inactivation of primary dehydrogenases. The filipin-uncoupled yeast respiration may likewise be attributed to an altered phosphate permeability of the yeast mitochondrial membranes.     

Mitochondria isolated in nearly isotonic KCl buffer: Focus on cardiolipin and organelle morphology

Rat liver mitochondria were isolated in parallel in two different isolation buffers: a standard buffer containing mannitol/sucrose and a nearly physiological KCl based solution. The two different organelle preparations were comparatively characterized by respiratory activity, heme content, microsomal and Golgi contamination, electron microscopy and lipid analyses. The substitution of saccharides with KCl in the isolation buffer does not induce the formation of mitoplasts or disruption of mitochondria. Mitochondria isolated in KCl buffer are coupled and able to maintain a stable transmembrane charge separation. A number of biochemical and functional differences between the two organelle preparations are described; in particular KCl mitochondria exhibit lower cardiolipin content and smaller intracristal compartments in comparison with the standard mitochondrial preparation.     

Effects of Postdecapitative Ischemia on Mitochondrial Respiration in Brain Tissue Homogenates

Mitochondria isolated from ischemic brain characteristically show changes in respiratory function. As conventional procedures for mitochondrial isolation yield a subpopulation of the total population and require extensive manipulation, it is unclear to what extent these changes are representative of mitochondria in the unfractionated tissue. We previously showed that the oxygen uptake by unfractionated forebrain homogenates, measured under two different sets of incubation conditions, provided information on some aspects of the respiratory activity of both the free and synaptosomal pools of mitochondria. Forebrain homogenates from animals subjected to 30 min of postdecapitative ischemia exhibited large reductions in oxygen uptake rates measured in a high K+ (mitochondrial) buffer in the presence of either ADP (44% of control values) or an uncoupling agent (45% of control values). These reductions in respiratory activity were comparable to alterations observed under the same conditions for mitochondria isolated from the ischemic brains. Similar alterations were seen in homogenates from three subregions: neocortex, hippocampus, and striatum. In a physiological buffer, in which oxygen uptake by homogenates largely resulted from activity of mitochondria within synaptosomes, there was little or no change in basal glucose-supported rates (79-96% of control values) and small reductions in maximal rates (63-81% of control values) measured in the presence of an uncoupling agent. These results suggest that alterations of respiratory function seen in isolated free mitochondria provide appropriate estimates of the dysfunction in the total free mitochondrial pool but that synaptosomal mitochondria may be less affected. Measurements of respiratory function of isolated synaptosomes from ischemic tissue provided further support for the relative preservation of synaptosomal mitochondria during ischemic insult.     

Enhanced rate of citrate export from cholesterol-rich hepatoma mitochondria. The truncated Krebs cycle and other metabolic ramifications of mitochondrial membrane cholesterol

Mitochondria isolated from rapidly growing, poorly differentiated Morris hepatoma 3924A have been found to export the citrate they generate from pyruvate, at a rate greater than four times that of control liver preparations. These 3924A mitochondria fail to exhibit state 3 respiration when either pyruvate or citrate are supplied as respiratory fuels. Nevertheless, substrates that join the Krebs cycle beyond citrate (viz. isocitrate, glutamate, alpha-ketoglutarate, and succinate) are readily oxidized by tumor 3924A mitochondria. Blocking the tricarboxylate anion exchange carrier with the citrate transport inhibitor 1,2,3-benzenetricarboxylate restores the ability of tumor 3924A mitochondria to respire with pyruvate or citrate. Slowly growing, minimally deviated Morris hepatoma 16 possesses mitochondria that do not display discernably altered respiratory patterns with pyruvate or citrate, but they do exhibit a 30% increase in the rate of citrate export relative to control liver preparations. Paralleling the preferential citrate export from tumor mitochondria is a dramatic enrichment of the tumor mitochondrial membranes with cholesterol. Hepatoma 3924A mitochondria possess a more than 5-fold enrichment in cholesterol, and those from tumor 16 display a 2-fold enrichment. When normal mitochondria, isolated from ACI strain rat liver, were enriched with cholesterol in vitro via a solid-state molecule transfer method employing Sephadex G-10 beads coated with cholesterol, they exhibited altered patterns of Krebs cycle metabolism that were qualitatively identical to those obtained with isolated Morris hepatoma mitochondria (which become enriched in membrane cholesterol endogenously during tumorigenesis). The enrichment of mitochondrial membranes with cholesterol, either by experimental manipulation in vitro or during the proliferation of the tumor in the host animal, promotes these metabolic changes directly, apparently by effecting a functional alteration in the operation of the tricarboxylate (citrate) exchange carrier of the inner mitochondrial membrane. These results highlight two related but incompletely understood phenomena as follows: 1) a functionally truncated Krebs cycle in cholesterol-rich tumor mitochondria, and 2) a mechanism for providing higher cytoplasmic levels of precursor metabolite intermediates which help sustain deregulated cholesterogenesis in hepatomas and other malignant neoplasms.     

Identification of a mitochondrial alcohol dehydrogenase in Schizosaccharomyces pombe: new insights into energy metabolism

In the present study we have shown that mitochondria isolated from Schizosaccharomyces pombe exhibit antimycin A-sensitive oxygen uptake activity that is exclusively dependent on ethanol and is inhibited by trifluoroethanol, a potent inhibitor of ADH (alcohol dehydrogenase). Ethanol-dependent respiratory activity has, to our knowledge, not been reported in S. pombe mitochondria to date, which is surprising as it has been concluded previously that only one ADH gene, encoding a cytosolic enzyme, occurs in this yeast. Spectrophotometric enzyme assays reveal that ADH activity in isolated mitochondria is increased approximately 16-fold by Triton X-100, which demonstrates that the enzyme is located in the matrix. Using genetic knockouts, we show conclusively that the novel mitochondrial ADH is encoded by adh4 and, as such, is unrelated to ADH isoenzymes found in mitochondria of other yeasts. By performing a modular-kinetic analysis of mitochondrial electron transfer, we furthermore show how ethanol-dependent respiratory activity (which involves oxidation of matrix-located NADH) compares with that observed when succinate or externally added NADH are used as substrates. This analysis reveals distinct kinetic differences between substrates which fully explain the lack of respiratory control generally observed during ethanol oxidation in yeast mitochondria.     

Populations of rat skeletal muscle mitochondria after exercise and immobilization

We slightly modified an existing procedure (Palmer et al., J. Biol. Chem. 252: 8731-8739, 1977) to isolate two distinct populations of mitochondria from rat skeletal muscle; initial brief Polytron homogenization released the subsarcolemmal mitochondria, and brief exposure of the resultant intact myofibrils to the proteolytic enzyme, Nagarse, extracted the intermyofibrillar mitochondria. The intermyofibrillar mitochondria differed from the subsarcolemmal mitochondr. ia by higher state III respiration measurements and enzymatic activities. These two populations of mitochondria were then isolated from the gastrocnemius muscle that had been induced to perform different amounts of contractile activity. The endurance training program of daily running significantly increased state III respiration and respiratory control index in the subsarcolemmal mitochondria, but the program did not increase these measurements in the intermyofibrillar mitochondria. In addition, 2 days of hindlimb immobilization resulted in a significant decrease in state II respiration and the respiratory control index of the subsarcolemmal mitochondria; however, immobilization did not affect the intermyofibrillar mitochondria. These measurements suggest that the subsarcolemmal mitochondria adapt in response to chronic changes in the level of contractile activity.     

The Influence of Mitochondrial Concentration and Storage on the Respiratory Control of Isolated Plant Mitochondria

The respiration of mitochondria isolated from various plant tissues was studied over a range of mitochondrial concentrations and at various times after isolation. Respiration at 25 C expressed as nanomoles of O₂ per minute per milligram of protein was constant for mitochondrial concentrations higher than some critical amount, usually 0.25 to 1.0 milligram of protein per reaction. Below this concentration the state 3 respiration rate declined and the mitochondria appeared to lose respiratory control. The respiration of isolated mitochondria stored in ice but measured at 25 C generally declined over long time periods although mitochondria from some tissues showed an initial increase. The results indicate that valid comparisons of the respiratory activity of mitochondria isolated from different tissues or from different parts of the same tissue cannot be made at least until the influence of the above factors has been evaluated.     

Changes in the Respiratory, Enzymatic, and Swelling and Contraction Properties of Mitochondria from Colytedons of Phaseolus vulgaris L. during Germination

Mitochondria isolated from cotyledons of germinating wax beans (Phaseolus vulgaris L.) showed fairly good respiratory control on days 1 and 2 after planting. The respiratory control was completely lost from days 3 to 5. During this period mitochondria were shown to be very leaky, losing about 88% of their total nicotinamide adenine dinucleotide to the suspending medium in a short time. The respiratory control was partially recovered by day 7, after which it completely disappeared again. By the use of differential centrifugation, the mitochondria were divided into subfractions by sequential centrifugation: 10,000g for 5 minutes, 25,000g for 5 minutes, and 40,000g for 5 minutes. The 10,000g subfraction was responsible for the recovery of mitochondrial activity (respiratory control value, adenosine diphosphate to oxygen ratio, and rate of oxygen utilization), on day 7. Activities of succinate dehydrogenase, cytochrome oxidase, pyruvate dehydrogenase, and isocitrate dehydrogenase from different mitochondrial subfractions of aging cotyledons were determined. In general, the enzyme activities, adenosine diphosphate to oxygen ratios, and the ability of mitochondria to swell and contract followed the same pattern as for respiratory control.     

Mitochondria from Zea mays leaf tissues: Differentiation of carbon assimilation and photorespiratory activity between mesophyll and bundle sheath cells

A procedure was developed to obtain intact and purified mitochondria from mesophyll and bundle sheath tissues of Zea mays L. cv. I.N.R.A. 180, an NADP⁺-malic enzyme type C₄ plant. There was little cross-contamination between the two mitochondrial fractions.
Both types of mitochondria oxidized NADH, succinate and malate with respiratory control. In mesophyll mitochondria malate oxidation was highly sensitive to KCN (85–90% inhibition of first state 3) and showed good respiratory control. In bundle sheath mitochondria malate oxidation was less sensitive to cyanide (75-80% inhibition) and showed poor respiratory control. Malate and NADH appeared to be the best substrates for respiratory activity. Mesophyil mitochondria could not oxidize glycine, whereas bundle sheath mitochondria could.
The results indicate that mesophyll and bundle sheath mitochondria of Zea mays are differentiated, not only with respect to the decarboxylation of malate but also with respect to the decarboxylation phase of photorespiration.     

A rapid method for the isolation of intact mitochondria from isolated rat liver cells.

A method is described for the preparation of intact mitochondria from isolated hepatocytesby sonication. Sonication of a suspension of rat liver cells for 10–30 s yields a homogenate from which tightly coupled mitochondria can be isolated. These mitochondria exhibit high respiratory control ratios and normal ADP:O ratios using glutamate plus malate, β-hydroxybutyrate, succinate, or ascorbate plus N,N,N′,N′-tetramethyl-p-phenylendiamine as substrates. The yield of mitochondrial protein is approximately 100–120 mg starting from 5 g of liver tissue. The mitochondrial fraction is essentially free of contaminating plasma membrane and microsomes and contains only small amounts of peroxisomes and lysosomes.     

Assessing mitochondrial dysfunction in cells

Assessing mitochondrial dysfunction requires definition of the dysfunction to be investigated. Usually, it is the ability of the mitochondria to make ATP appropriately in response to energy demands. Where other functions are of interest, tailored solutions are required. Dysfunction can be assessed in isolated mitochondria, in cells or in vivo, with different balances between precise experimental control and physiological relevance. There are many methods to measure mitochondrial function and dysfunction in these systems. Generally, measurements of fluxes give more information about the ability to make ATP than do measurements of intermediates and potentials. For isolated mitochondria, the best assay is mitochondrial respiratory control: the increase in respiration rate in response to ADP. For intact cells, the best assay is the equivalent measurement of cell respiratory control, which reports the rate of ATP production, the proton leak rate, the coupling efficiency, the maximum respiratory rate, the respiratory control ratio and the spare respiratory capacity. Measurements of membrane potential provide useful additional information. Measurement of both respiration and potential during appropriate titrations enables the identification of the primary sites of effectors and the distribution of control, allowing deeper quantitative analyses. Many other measurements in current use can be more problematic, as discussed in the present review.     

The maturation of the inner membrane of foetal rat liver mitochondria.

A new method was devised for the isolation of foetal and neonatal rat lvier mitochondria, giving higher yields than conventional methods. 2. During development from the perinatal period to the mature adult, the ratio of cytochrome oxidase/succinate-cytochrome c reductase changes. 3. The inner mitochondrial membrane of foetal liver mitochondria possesses virtually no osmotic activity; the permeability to sucrose decreases with increasing developmental age. 4. Foetal rat liver mitochondria possess only marginal respiratory control and do not maintain Ca2+-induced respiration; they also swell in respiratory-control medium in the absence of substrate. ATP enhances respiratory control and prevents swelling, adenylyl imidodiphosphate, ATP+atractyloside enhance the R.C.I. (respiratory control index), Ca2+-induced respiratory control and prevent swelling, whereas GTP and low concentrations of ADP have none of these actions. It is concluded that the effect of ATP depends on steric interaction with the inner mitochondrial membrane. 5. When 1-day pre-partum foetuses are obtained by Caesarean section and maintained in a Humidicrib for 90 min, mitochondrial maturation is "triggered", so that their R.C.I. is enhanced and no ATP is required to support Ca2+-dependent respiratory control or to inhibit mitochondrial swelling. 6. It is concluded that foetal rat liver mitochondria in utero do not respire, although they are capable of oxidative phosphorylation in spite of their low R.C.I. The different environmental conditions which the neonatal rat encounters ex utero enable the hepatic mitochondria to produce ATP, which interacts with the inner mitochondrial membrane to enhance oxidative phosphorylation by an autocatalytic mechanism.     

Restoration of mitochondrial energy-linked reactions following dexamethasone treatment of rats infected with the liver fluke Fasciolahepatica

Mitochondria isolated from male Wistar rats experimentally infected with the common liver fluke, Fasciolahepatica, exhibit loss of respiratory control from 2 weeks post-infection (Rule, et al. (1989) Biochem. J. 260, 517–523). We now report that subcutaneous injections of the anti-inflammatory drug, dexamethasone, during the final week of infection prevented the mitochondrial uncoupling and restored respiratory control almost to the levels of uninfected controls. Further investigations have shown that mitochondria from infected rat livers are unable to synthesize ATP and that abnormal respiration is also evident in hepatocytes isolated from infected rats. These abnormalities were absent when infected rats were treated with dexamethasone. In addition, liver mitochondrial function in infected, congenitally athymic, nude rats (CBH/R nu/nu) was not significantly different from that in uninfected nude or Wistar controls. These results provide evidence that the mitochondrial dysfunction in fascioliasis is host-mediated and that T lymphocytes in particular may be involved.