Comparison of RNA's transcribed in vivo from mitochondrial DNA of cytoplasmic and chromosomal respiratory deficient mutants

Summary In some respiratory deficient cytoplasmic mutants, the buoyant density of mitochondrial DNA is changed to detectable degrees, as compared to that of wild type strain: since this density shift suggests an important modification of polynucleotide sequence in mitochondrial DNA, we examined sequence homology between mitochondrial DNA of the respiratory mutants issued from cytoplasmic or chromosomal mutations. Mitochondrial DNA, nuclear DNA and total RNA were extracted from ϱ⁺ cells (wild type, respiratory sufficient) and from ϱ^- cells (cytoplasmic “petite colonie” mutant, respiratory deficient), and molecular hybridization experiments were carried out between them. When ϱ⁺ RNA × ϱ⁺ mitochondrial DNA, formed roughly twice as much hybrids as the heterologous cross, ϱ⁺ RNA × ϱ¹ mitochondrial DNA. Reciprocally, when ϱ^- RNA was hybridized to ϱ⁺ and ϱ^- mitochondrial DNA, the homologous cross produced again about twice as much hybrids as the heterologous cross. These results were confirmed by dehydridization-rehybridization experiments: the RNA separated from the hybrids “ϱ⁺ RNA × ϱ⁺ mit-DNA” as well as the RNA separated from the hybrids “ϱ⁺ RNA × ϱ^- mit-DNA” were rehybridized either with ϱ⁺ or ϱ^- mit-DNA. A preferential hybridization of ϱ⁺ RNA with ϱ⁺ mit-DNA, and of ϱ^- RNA with ϱ^- mit-DNA was clearly observed. On the contrary, ϱ⁺ and ϱ^- nuclear DNA did not distinguish ϱ⁺ or ϱ^- RNA. The same series of experiments were carried out using a chromosomal mutation,P ₇ to p₇, leading to the same respiratory deficient phenotype. We found that the p₇ mutation did not introduce a detectable change in mitochondrial DNA base sequence. The results support the idea that the cytoplasmic hereditary factor, ϱ, resides in mitochondrial DNA and that the ϱ^- mutations studied correspond to a dispersed sequence modification covering about a half of the total mitochondrial DNA genome, leaving the other half unchanged. Alternatively, the results can be explained by a hypothesis in which mitochondrial DNA is a heterogeneous population of the molecules having more or less related sequences and the mutation leads to a selection of certain molecular species. 4 S RNA was found to contain RNA species which hybridize with mitochondrial DNA. The degree of hybridization was very different for ϱ⁺ and ϱ^- S RNA, when they were hybridized with either ϱ⁺ or ϱ^- mitochondrial DNA.     

The development of an isokinetic squat device: reliability and relationship to functional performance

The aims of the present study were: (1) to assess aerobic metabolism in paraplegic (P) athletes (spinal lesion level, T4–L3) by means of peak oxygen uptake (V˙O_2peak) and ventilatory threshold (VT), and (2) to determine the nature of exercise limitation in these athletes by means of cardioventilatory responses at peak exercise. Eight P athletes underwent conventional spirographic measurements and then performed an incremental wheelchair exercise on an adapted treadmill. Ventilatory data were collected every minute using an automated metabolic system: ventilation (l · min⁻¹), oxygen uptake (V˙O₂, l · min⁻¹, ml · min⁻¹ · kg⁻¹), carbon dioxide production (V˙CO₂, ml · min⁻¹), respiratory exchange ratio, breathing frequency and tidal volume. Heart rate (HR, beats · min⁻¹) was collected with the aid of a standard electrocardiogram. V˙O_2peak was determined using conventional criteria. VT was determined by the breakpoint in the V˙CO₂−V˙O₂ relationship, and is expressed as the absolute VT (V˙O₂, ml · min⁻¹ · kg⁻¹) and relative VT (percentage of V˙O_2peak). Spirometric values and cardioventilatory responses at rest and at peak exercise allowed the measurement of ventilatory reserve (VR), heart rate reserve (HRr), heart rate response (HRR), and O₂ pulse (O₂ P). Results showed a V˙O_2peak value of 40.6 (2.5) ml · min⁻¹ · kg⁻¹, an absolute VT detected at 23.1 (1.5) ml · min⁻¹ · kg⁻¹ V˙O₂ and a relative VT at 56.4 (2.2)% V˙O_2peak. HRr [15.8 (3.2) beats · min⁻¹], HRR [48.6 (4.3) beat · l⁻¹], and O₂ P [0.23 (0.02) ml · kg⁻¹ · beat⁻¹] were normal, whereas VR at peak exercise [42.7 (2.4)%] was increased. As wheelchair exercise excluded the use of an able-bodied (AB) control group, we compared our V˙O_2peak and VT results with those for other P subjects and AB controls reported in the literature, and we compared our cardioventilatory responses with those for respiratory and cardiac patients. The low V˙O_2peak values obtained compared with subject values obtained during an arm-crank exercise may be due to a reduced active muscle mass. Absolute VT was somewhat comparable to that of AB subjects, mainly due to the similar muscle mass involved in wheelchair and arm-crank exercise by P and AB subjects, respectively. The increased VR, as reported in patients with chronic heart failure, suggested that P athletes exhibited cardiac limitation at peak exercise, and this contributed to the lower V˙O_2peak measured in these subjects. Accepted: 22 April 1997     

Inhibition of Brain Energy Metabolism by the Branched-chain Amino Acids Accumulating in Maple Syrup Urine Disease

In the present work we investigated the in vitro effect of the branched-chain amino acids (BCAA) accumulating in maple syrup urine disease (MSUD) on some parameters of energy metabolism in cerebral cortex of rats. ¹⁴CO₂ production from [1-¹⁴C]acetate, [1-5-¹⁴C]citrate and [U-¹⁴C]glucose, as well as glucose uptake by the brain were evaluated by incubating cortical prisms from 30-day-old rats in the absence (controls) or presence of leucine (Leu), valine (Val) or isoleucine (Ile). All amino acids significantly reduced ¹⁴CO₂ production by around 20–55%, in contrast to glucose utilization, which was significantly increased by up to 90%. Furthermore, Leu significantly inhibited the activity of the respiratory chain complex IV, whereas Val and Ile markedly inhibited complexes II–III, III and IV by up to 40%. We also observed that trolox (α-tocopherol) and creatine totally prevented the inhibitory effects provoked by the BCAA on the respiratory chain complex activities, suggesting that free radicals were involved in these effects. The results indicate that the major metabolites accumulating in MSUD disturb brain aerobic metabolism by compromising the citric acid cycle and the electron flow through the respiratory chain. We presume that these findings may be of relevance to the understanding of the pathophysiology of the neurological dysfunction of MSUD patients.     

Thermoregulatory changes in the cold induced by physical training in humans

It has previously been demonstrated that metabolic heat production (M˙) during cold exposure at rest was related to maximal oxygen uptake (O_2max). Consequently, an increase in O_2max could allow an increase M˙ in the cold. The aim of the present study was therefore to test this hypothesis. Eight male volunteers undertook interval training (periods of 25% V˙O_2max of 30-s duration and 110% V˙O_2max of 60-s duration until exhaustion, five times a week over 8 weeks) to increase V˙O_2max. Both before and after this physical training, they were subjected to a 10^∘, 5^∘ and 1^∘C 2-h cold air test in a climatic chamber. During the cold exposure, rectal temperature (T _re), tympanic temperature (T _ty), mean skin temperature () and M˙ were measured as well as the time to onset of shivering (t) and body temperatures () at t. The results showed that physical training involved an increase in O_2max (14%–15%, P < 0.05). During the cold exposure, T _re was higher after training both at 10^∘,5^∘ and 1^∘C (P < 0.05) whereas were not significantly changed. However, an increase in the sensitivity of the thermoregulatory system was attested by a decreased t at higher These slight physiological changes found after training were not related to the increases in V˙O_2max. In conclusion, this study demonstrated that interval training induced slight thermoregulatory changes unrelated to changes in V˙O_2max and it suggested that M˙ during cold exposure could be related mainly to the level of V˙O_2max observed before training, since increases in V˙O_2max did not modify M˙. Accepted: 8 April 1998     

NADH oxidation drives respiratory Na+ transport in mitochondria from Yarrowia lipolytica

It is generally assumed that respiratory complexes exclusively use protons to energize the inner mitochondrial membrane. Here we show that oxidation of NADH by submitochondrial particles (SMPs) from the yeast Yarrowia lipolytica is coupled to protonophore-resistant Na⁺ uptake, indicating that a redox-driven, primary Na⁺ pump is operative in the inner mitochondrial membrane. By purification and reconstitution into proteoliposomes, a respiratory NADH dehydrogenase was identified which coupled NADH-dependent reduction of ubiquinone (1.4 μmol min⁻¹ mg⁻¹) to Na⁺ translocation (2.0 μmol min⁻¹ mg⁻¹). NADH-driven Na⁺ transport was sensitive towards rotenone, a specific inhibitor of complex I. We conclude that mitochondria from Y. lipolytica contain a NADH-driven Na⁺ pump and propose that it represents the complex I of the respiratory chain. Our study indicates that energy conversion by mitochondria does not exclusively rely on the proton motive force but may benefit from the electrochemical Na⁺ gradient established by complex I. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Putative Structural and Functional Coupling of the Mitochondrial BKCa Channel to the Respiratory Chain

Potassium channels have been found in the inner mitochondrial membranes of various cells. These channels regulate the mitochondrial membrane potential, the matrix volume and respiration. The activation of these channels is cytoprotective. In our study, the single-channel activity of a large-conductance Ca²⁺-regulated potassium channel (mitoBK_Ca channel) was measured by patch-clamping mitoplasts isolated from the human astrocytoma (glioblastoma) U-87 MG cell line. A potassium-selective current was recorded with a mean conductance of 290 pS in symmetrical 150 mM KCl solution. The channel was activated by Ca²⁺ at micromolar concentrations and by the potassium channel opener NS1619. The channel was inhibited by paxilline and iberiotoxin, known inhibitors of BK_Ca channels. Western blot analysis, immuno-gold electron microscopy, high-resolution immunofluorescence assays and polymerase chain reaction demonstrated the presence of the BK_Ca channel β4 subunit in the inner mitochondrial membrane of the human astrocytoma cells. We showed that substrates of the respiratory chain, such as NADH, succinate, and glutamate/malate, decrease the activity of the channel at positive voltages. This effect was abolished by rotenone, antimycin and cyanide, inhibitors of the respiratory chain. The putative interaction of the β4 subunit of mitoBK_Ca with cytochrome c oxidase was demonstrated using blue native electrophoresis. Our findings indicate possible structural and functional coupling of the mitoBK_Ca channel with the mitochondrial respiratory chain in human astrocytoma U-87 MG cells.     

Mitochondrial function in the yeast form of the pathogenic fungus <Emphasis Type="Italic">Paracoccidioides brasiliensis</Emphasis>

Differences between the respiratory chain of the fungus Paracoccidioides brasiliensis and its mammalian host are reported. Respiration, membrane potential, and oxidative phosphorylation in mitochondria from P. brasiliensis spheroplasts were evaluated in situ, and the presence of a complete (Complex I–V) functional respiratory chain was demonstrated. In succinate-energized mitochondria, ADP induced a transition from resting to phosphorylating respiration. The presence of an alternative NADH–ubiquinone oxidoreductase was indicated by: (i) the ability to oxidize exogenous NADH and (ii) the lack of sensitivity to rotenone and presence of sensitivity to flavone. Malate/NAD⁺-supported respiration suggested the presence of either a mitochondrial pyridine transporter or a glyoxylate pathway contributing to NADH and/or succinate production. Partial sensitivity of NADH/succinate-supported respiration to antimycin A and cyanide, as well as sensitivity to benzohydroxamic acids, suggested the presence of an alternative oxidase in the yeast form of the fungus. An increase in activity and gene expression of the alternative NADH dehydrogenase throughout the yeast’s exponential growth phase was observed. This increase was coupled with a decrease in Complex I activity and gene expression of its subunit 6. These results support the existence of alternative respiratory chain pathways in addition to Complex I, as well as the utilization of NADH-linked substrates by P. brasiliensis. These specific components of the respiratory chain could be useful for further research and development of pharmacological agents against the fungus.     

Phosphorylation coupled to O2 and nitrate reduction inPseudomonas saccharophila grown anaerobically with succinate and nitrate

Cell-free membrane preparations fromPseudomanas saccharophila grown anterobically with succinate and nitrate catalyzed NADH oxidation by O₂ and nitrate, yielding P/O and P/NO₃ ⁻-reduced ratios of 0.76 and 0.51, respectively. Succinate oxidation yielded a P/O ratio of 0.44 and a P/NO₃ ⁻-reduced ratio of 0.08. Ascorbate oxidation by O₂ or nitrate was not coupled with ATP generation. The NADH- or succinate-linked oxidative phosphorylation was uncoupled by classical uncoupling agents: moreover, the aerobic and the anaerobic oxidation of NADH and succinate, as well as the coupled ATP synthesis, was inhibited by low concentrations of respiratory chain inhibitors. In addition, oligomycin was a potent inhibitor of ATP generation in this system.     

Oxygen uptake does not increase linearly at high power outputs during incremental exercise test in humans

A group of 12 healthy non-smoking men [mean age 22.3 (SD 1.1) years], performed an incremental exercise test. The test started at 30 W, followed by increases in power output (P) of 30 W every 3 min, until exhaustion. Blood samples were taken from an antecubital vein for determination of plasma concentration lactate [La⁻]_pl and acid-base balance variables. Below the lactate threshold (LT) defined in this study as the highest P above which a sustained increase in [La⁻]_pl was observed (at least 0.5 mmol · l⁻¹ within 3 min), the pulmonary oxygen uptake (V˙O₂) measured breath-by-breath, showed a linear relationship with P. However, at P above LT [in this study 135 (SD 30) W] there was an additional accumulating increase in V˙O₂ above that expected from the increase in P alone. The magnitude of this effect was illustrated by the difference in the final P observed at maximal oxygen uptake (V˙O_2max) during the incremental exercise test (P _max,obs at V˙O_2max) and the expected power output at V˙O_2max(P _max,exp at V˙O_2max) predicted from the linear V˙O₂-P relationship derived from the data collected below LT. The P _max,obs at V˙O_2max amounting to 270 (SD 19) W was 65.1 (SD 35) W (19%) lower (P<0.01) than the P _max,exp at V˙O_{2max .} The mean value of V˙O_2max reached at P _max,obs amounted to 3555 (SD 226) ml · min⁻¹ which was 572 (SD 269) ml · min⁻¹ higher (P<0.01) than the V˙O₂ expected at this P, calculated from the linear relationship between V˙O₂ and P derived from the data collected below LT. This fall in locomotory efficiency expressed by the additional increase in V˙O₂, amounting to 572 (SD 269) ml O₂ · min⁻¹, was accompanied by a significant increase in [La⁻]_pl amounting to 7.04 (SD 2.2) mmol · l⁻¹, a significant increase in blood hydrogen ion concentration ([H⁺]_b) to 7.4 (SD 3) nmol · l⁻¹ and a significant fall in blood bicarbonate concentration to 5.78 (SD 1.7) mmol · l⁻¹, in relation to the values measured at the P of the LT. We also correlated the individual values of the additional V˙O₂ with the increases (Δ) in variables [La⁻]_pl and Δ[H⁺]_b. The Δ values for [La⁻]_pl and Δ[H⁺]_b were expressed as the differences between values reached at the P _max,obs at V˙O_2max and the values at LT. No significant correlations between the additional V˙O₂ and Δ[La⁻]_pl on [H⁺]_b were found. In conclusion, when performing an incremental exercise test, exceeding P corresponding to LT was accompanied by a significant additional increase in V˙O₂ above that expected from the linear relationship between V˙O₂ and P occurring at lower P. However, the magnitude of the additional increase in V˙O₂ did not correlate with the magnitude of the increases in [La⁻]_pl and [H⁺]_b reached in the final stages of the incremental test. Accepted: 30 October 1997     

Clorgyline and other propargylamine derivatives as inhibitors of succinate-dependent H<Subscript>2</Subscript>O<Subscript>2</Subscript> release at NADH:UBIQUINONE oxidoreductase (Complex I) in brain mitochondria

Complex I is the main O₂ ⁻ producer of the mitochondrial respiratory chain. O₂ ⁻ release is low with NAD-linked substrates and increases strongly during succinate oxidation, which increases the QH₂/Q ratio and is rotenone sensitive. We show that the succinate dependent O₂ ⁻ production (measured as H₂O₂ release) is inhibited by propargylamine containing compounds (clorgyline, CGP 3466B, rasagiline and TVP-1012). The inhibition does not affect membrane potential and is unaffected by ΔpH modifications. Mitochondrial respiration is similarly unaffected. The propargylamines inhibition of O₂ ⁻/H₂O₂ production is monitored also in the presence of the Parkinson's disease toxin dopaminochrome which stimulates O₂ ⁻ release. Propargylamine-containing compounds are the first pharmacological inhibitors described for O₂ ⁻ release at Complex I.     

Oxidation of reduced nicotinamide hypoxanthine dinucleotide by intact rat liver mitochondria

1. The rate of NADH oxidation catalyzed by intact rat liver mitochondria is greatly stimulated in the presence of oxidized nicotinamide hypoxanthine dinucleotide (NHD⁺).2. Mitochondrial oxidation of external NHDH is from 20- to 40-fold more rapid than that of NADH, although these coenzymes are oxidized at similar rates by sonicated mitochondria.3. NADH and NADPH inhibit, while NADP⁺ stimulates NHDH oxidation.4. NHDH oxidation is inhibited by rotenone and CN^?.5. NHDH oxidation is coupled to the phosphorylation of ADP to ATP, yielding P:2e^? ratios approaching 3.6. These studies indicate that external NHDH is oxidized by the intramito-chondrial respiratory chain NADH dehydrogenase and that the inner mitochondrial membrane is significantly more permeable to NHDH than to NADH. Mammalian liver mitochondria have been reported to catalyze the enzymatic deamination of NAD(H) to NHD(H) [Buniatian, H. C. (1970) in Handbook of Neurochemistry (Lajtha, A., ed.), Vol. 3, pp. 399–411, Plenum Press, London and New York; Movcessian, S. G. and Manassian, R. F. (1967) in Problems of Brain Biochemistry, Vol. 3, pp. 53–66, Academic Press, Yerevan], suggesting a metabolic function for the deaminated analogue. It is concluded that this deamination reaction may be operative in a mechanism for the oxidation of cytoplasmic NADH by the respiratory chain.     

An electron-transport system associated with the outer membrane of liver mitochondria. A biochemical and morphological study

Preparations of rat-liver mitochondria catalyze the oxidation of exogenous NADH by added cytochrome c or ferricyanide by a reaction that is insensitive to the respiratory chain inhibitors, antimycin A, amytal, and rotenone, and is not coupled to phosphorylation. Experiments with tritiated NADH are described which demonstrate that this "external" pathway of NADH oxidation resembles stereochemically the NADH-cytochrome c reductase system of liver microsomes, and differs from the respiratory chain-linked NADH dehydrogenase. Enzyme distributation data are presented which substantiate the conclusion that microsomal contamination cannot account for the rotenone-insensitive NADH-cytochrome c reductase activity observed with the mitochondria. A procedure is developed, based on swelling and shrinking of the mitochondria followed by sonication and density gradient centrifugation, which permits the separation of two particulate subfractions, one containing the bulk of the respiratory chain components, and the other the bulk of the rotenone-insensitive NADH-cytochrome c reductase system. Morphological evidence supports the conclusion that the former subfraction consists of mitochondria devoid of outer membrane, and that the latter represents derivatives of the outer membrane. The data indicate that the electron-transport system associated with the mitochondrial outer membrane involves catalytic components similar to, or identical with, the microsomal NADH-cytochrome b₅ reductase and cytochrome b₅.     

The interaction of rubroskyrin, a modified bis-anthraquinone pigment fromPenicillium islandicum Sopp, with respiratory chain of liver mitochondria

Summary  Rubroskyrin, a modified bisanthraquinone pigment from an yellow rice moldPenicillium islandicum Sopp, was examined for its redox-interaction with the mitochondrial respiratory chain by using rat liver submitochondrial particles (SMP) and was compared with luteoskyrin and rugulosin. Rubroskyrin showed a redox interaction with the NAD-linked respiratory chain of SMP, promoting NADH oxidase in the presence of rotenone, a specific inhibitor to coupling site I of the respiratory chain. Rubroskyrin-mediated NADH oxidase was not inhibited by antimycin A and cyanide, inhibitors to coupling sites II and III, respectively, indicating a generation of an electron transport shunt from a rotenone-insensitive site of NADH dehydrogenase (complex I) to dissolved oxygen. An electrontransport shunt to cytochromec oxidase from complex I was also observed in the experiment with cytochromec and antimycin A. Rubroskyrin did not interact with succinate-linked respiratory chain. Such enzymatic redox response which generates electron transport shunt was not detected for luteoskyrin and rugulosin in the present study.     

The electron transport system of Alcaligenes eutrophus H16

In a previous work (Kömen et al. 1991) it has been concluded that membrane fragments isolated from autotrophically grown Alcaligenes eutrophus H16 contain several iron-sulphur centres along with haems of a-, b-, c-, and d-type. These redox components have been proposed to be part of a branched respiratory chain leading to multiple membrane bound oxidases. Here, some of the respiratory activities catalyzed by membrane fragments from wild type cells of A. eutrophus (H16) and, for comparison, Paracoccus denitrificans, have been investigated through the use of electron transport inhibitors. Cyanide (CN^-) titration curves indicated that in A. eutrophus H16 oxidation of succinate and H₂ preferentially proceeds via the cytochrome c oxidase(s) branch (I ₅₀=2 · 10^-5 M) whereas the NADH dependent respiration started being inhibited at higher CN^- concentrations (I ₅₀=5 · 10^-4 M). In membranes isolated from both, cells harvested at late growth-phase (OD 12) and from a mutant deficient in cytochrome c oxidase activity (A. eutrophus RK1), respiration was insensitive to low CN^- concentrations (< 10^-4 M), and it was sustained by the high catalytic activities of two quinol oxidases. These alternative oxidases of b- (formally o-) and d-type showed different sensitivities to KCN (I ₅₀=10^-3 M and 10^-2 M, respectively). Interestingly, the cytochrome c oxidase(s) dependent respiration of H16 membranes was insensitive to antimycin A but largely inhibited by myxothiazol (10^-6 M). This, and previous work (Kömen et al. 1991), suggest that although the respiratory chain of A. eutrophus is endowed with a putative bc ₁ complex, its biochemical nature and role in respiration of this organism are apparently different from those of P. denitrificans. The peculiarity of the respiratory chain of A. eutrophus is confirmed by the rotenone insensitivity of the NADH oxidation in both protoplasts and membrane fragments from wild type and soluble hydrogenase deficient cells (HF14 and HF160). A tentative model of the respiratory chain of autotrophically grown A. eutrophus is presented.     

Dependence of H2O2 Formation by Rat Heart Mitochondria on Substrate Availability and Donor Age

We have examined the substrate specificity and inhibitor sensitivity of H₂O₂ formation by rat heart mitochondria. Active H₂O₂ production requires both a high fractional reduction of Complex I (indexed by NADH/NAD⁺ + NADH ratio) and a high membrane potential, . These conditions are achieved with supraphysiological concentrations of succinate. With physiological concentrations of NAD-linked substrates, rates of H₂O₂ formation are much lower (less than 0.1% of respiratory chain electron flux) but may be stimulated by the Complex III inhibitor antimycin A, but not by myxothiazol. Addition of Mn²⁺ to give 10 nmol/mg of mitochondrial protein enhances H₂O₂ production with all substrate combinations, possibly by repleting mitochondrial superoxide dismutase with this cation. Contrary to previously published work, no increased activity of H₂O₂ production was found with heart mitochondria from senescent (24 month) rats, relative to young adults (6 month).     

Quinone and oxyradical scavenging properties of N-acetylcysteine prevent dopamine mediated inhibition of Na+, K+-ATPase and mitochondrial electron transport chain activity in rat brain: Implications in the neuroprotective therapy of Parkinson's disease

Dopamine oxidation products such as H₂O₂ and reactive quinones have been held responsible for various toxic actions of dopamine, which have implications in the aetiopathogenesis of Parkinson's disease. This study has shown that N-acetylcysteine (0.25–1 mm) is a potent scavenger of both H₂O₂ and toxic quinones derived from dopamine and it further prevents dopamine mediated inhibition of Na⁺,K⁺-ATPase activity and mitochondrial respiratory chain function. The quinone scavenging ability of N-acetylcysteine is presumably related to its protective effect against dopamine mediated inhibition of mitochondrial respiratory chain activity. However, both H₂O₂ scavenging and quinone scavenging properties of N-acetylcysteine probably account for its protective effect against Na⁺,K⁺-ATPase inhibition induced by dopamine. The results have important implications in the neuroprotective therapy of sporadic Parkinson's disease since inactivation of mitochondrial respiratory activity and Na⁺,K⁺-ATPase may trigger intracellular damage pathways leading to the death of nigral dopaminergic neurons.     

Oxygen uptake during moderate intensity running: response following a single bout of interval training

Eight male endurance runners [mean ± (SD): age 25 (6) years; height 1.79 (0.06) m; body mass 70.5 (6.0) kg; % body fat 12.5 (3.2); maximal oxygen consumption (V˙O_2max 62.9 (1.7) ml · kg⁻¹ · min⁻¹] performed an interval training session, preceded immediately by test 1, followed after 1 h by test 2, and after 72 h by test 3. The training session was six 800-m intervals at 1 km · h⁻¹ below the velocity achieved at V˙O_2max with 3 min of recovery between each interval. Tests 1, 2 and 3 were identical, and included collection of expired gas, measurement of ventilatory frequency (f _v ), heart rate (f _c), rate of perceived exertion (RPE), and blood lactate concentration ([La⁻]_B) during the final 5 min of 15 min of running at 50% of the velocity achieved at V˙O_2max (50% −V˙O_2max).␣Oxygen uptake (V˙O₂), ventilation (V˙ _E ), and respiratory exchange ratio (R) were subsequently determined from duplicate expired gas collections. Body mass and plasma volume changes were measured preceding and immediately following the training session, and before tests 1–3. Subjects ingested water immediately following the training session, the volume of which was determined from the loss of body mass during the session. Repeated measures analysis of variance with multiple comparison (Tukey) was used to test differences between results. No significant differences in body mass or plasma volume existed between the three test stages, indicating that the differences recorded for the measured parameters could not be attributed to changes in body mass or plasma volume between tests, and that rehydration after the interval training session was successful. A significant (P < 0.05) increase was found from test 1 to test 2 [mean (SD)] for V˙O₂ [2.128 (0.147) to 2.200 (0.140) 1 · min⁻¹], f _c [125 (17) to 132 (16) beats · min⁻¹], and RPE [9 (2) to 11 (2)]. A significant (P < 0.05) decrease was found for submaximal R [0.89 (0.03) to 0.85 (0.04)]. These results suggest that alterations in V˙O₂ during moderate-intensity, constant-velocity running do occur following heavy-intensity endurance running training, and that this is due to factors in addition to changed substrate metabolism towards greater fat utilisation, which could explain only 31% of the increase in V˙O₂. Accepted: 8 December 1997     

The role of the Krebs cycle in the generation of intramitochondrial reducing equivalents for the 11 beta-hydroxylation of deoxycorticosterone in isolated rat adrenal cells

Isolated rat adrenal cells were used to study the possible pathways of intramitochondrial NADPH generation for 11β-hydroxylation of 11-deoxycorticosterone. Pyruvate was efficiently utilized by the mitochondria as shown by evolution of ¹⁴CO₂ from [1-¹⁴C]- and [2-¹⁴C]pyruvate. Citrate, isocitrate, succinate, and malate were not utilized by intact cells due to their inability to permeate the plasma membrane. For every mole of corticosterone formed, 1.9 and 0.8 moles of ¹⁴CO₂ were formed from [1-¹⁴C]- and [2-¹⁴C]pyruvate, respectively, indicating that pyruvate dehydrogenase was quite active and supplied acetyl C?oA to the Krebs cycle. Fluorocitrate and 2,4-dinitrophenol inhibited 11β-hydroxylation of 11-deoxycorticosterone as well as the production of ¹⁴CO₂ from [2-¹⁴C]pyruvate. Comparison of data with the two inhibitors showed that for the same percentage of inhibition of ¹⁴CO₂ production, the inhibition of 11β-hydroxylation was greater with 2,4-dinitrophenol than with fluorocitrate. It is concluded that operation of the Krebs cycle may be essential for 11β-hydroxylation to occur primarily because NADH generated by the cycle provides ATP, via the respiratory chain, as well as the substrate for the energy-linked transhydrogenase that forms NADPH. The NADPH required for 11β-hydroxylation seems to be derived to a large extent via the energy-linked transhydrogenase.