Thermal Sensitivity of Mitochondrial Respiration Efficiency and Protein Phosphorylation in the Clam Mercenaria mercenaria

The mitochondria of intertidal invertebrates continue to function when organisms are exposed to rapid substantial shifts in temperature. To test if mitochondrial physiology of the clam Mercenaria mercenaria is compromised under elevated temperatures, we measured mitochondrial respiration efficiency at 15°C, 18°C, and 21°C using a novel, high-throughput, microplate respirometry methodology developed for this study. Though phosphorylating (state 3) and resting (state 4) respiration rates were unaffected over this temperature range, respiratory control ratios (RCRs: ratio of state 3 to state 4 respiration rates) decreased significantly above 18°C (p < 0.05). The drop in RCR was not associated with reduction of phosphorylation efficiency, suggesting that, while aerobic scope of mitochondrial respiration is limited at elevated temperatures, mitochondria continue to efficiently produce adenosine triphosphate. We further investigated the response of clam mitochondria to elevated temperatures by monitoring phosphorylation of mitochondrial protein. Three proteins clearly demonstrated significant time- and temperature-specific phosphorylation patterns. The protein-specific patterns of phosphorylation may suggest that a suite of protein kinases and phosphatases regulate mitochondrial physiology in response to temperature. Thus, while aerobic scope of clam mitochondrial respiration is reduced at moderate temperatures, specific protein phosphorylation responses reflect large shifts in function that are initiated within the organelle at higher temperatures.     

The Effect of Temperature on Oxidative Phosphorylation with Insect Flight Muscle Mitochondria

The effect of different temperatures on the biochemical activity and morphology of insect flight muscle mitochondria was examined. It was found that respiration and phosphorylation have the same thermal response at temperatures of 25°C. and below. The energy of activation for both systems is approximately 12,300 calories. Oxidation and phosphorylation can be uncoupled effectively by temperature, for at temperatures above 25°C. there is more rapid heat inactivation of phosphorylation. This is evident from reduced P/O values as well as from morphological deterioration in the mitochondrial population. The thermal response of both this sarcosomal enzyme system and the respiration in the living fly are quantitatively similar.     

Effect of Low Temperature lmbibition on Mito chondrium Respiration and Phosphorylation of PEG Primed Soybean Seed

Cotyledon mitochondrium respiration and oxidative phosphorylation activity of PEG primed and unprimed (control) soybean seeds which have been exposed to low temperature imbibition before germination are studied. The ADP stimulated respiration rates of control mitochondria are evidently higher than state Ⅲ respiration rates of mitochondria from primed seed when L-Mal, α-Kg and Succ are used as substrates respectively. The mitochondria from the unprimed do not possess respiratory control (RC.) On the contrary, mitochondria from the primed, even after seeds being exposed to 2–3 ℃ imbibition for 24 h, phosphorylate normally. The ADP/O and RC values are consistent with those of theoretical expectation. When NADH is used as substrate, unprimed seed mitochondria still possess oxidative phosphorylation activity, while ADP/O and RC values are obviously lower than those of mitochondria from the primed. The emerging sequence of the activity of the diverse phosphorylation sites during germination is also studied. When a different substrate is used, the emerging sequence of the primed is as follows: 1. NADH (12 h), 2.α-Kg (24 h), 3. L-Mal and Succ (48 h). This corresponds to occurrence sequence of ADP stimulated respiration in control mitochondria. The above results show that low temperature imbibition has an irreversible destructive effect on oxidative phosphorylation activity of control mitochondria, and PEG priming has a protective effect on structure and function of the mitochondria under low temperature imbibition stress. The mechanism of soybean imbibitional chilling injury and protective effect of PEG priming are discussed.     

Effect of Temperature on Respiration of Mitochondria and Shoot Segments from Cold hardened and Nonhardened Wheat and Rye Seedlings

The effect of temperature on respiration of mitochondria and tissue segments from three wheat (Triticum aestivum L.) and one rye (Secale cereale L.) cultivar grown at 2 and 24 C has been examined. Discontinuities in Arrhenius plots of respiratory activity against temperature were observed for mitochondria and tissue segments from seedlings grown at both temperatures. The rates of respiration decreased abruptly below the transition temperatures, resulting in increased energy of activation values for respiration. Transition temperatures were observed from 6 to 10 C during tissue segment respiration, and from 10 to 14 C during respiration by isolated mitochondria. Respiratory control and efficiency of phosphorylation were not affected markedly by either reaction temperature or growth temperature of the seedlings. No correlation was observed between the cold hardiness of the cultivars and the temperature at which structural transitions occurred in the mitochondria. Dry matter content of the seedlings increased markedly during growth at 2 C, but no appreciable changes in the levels of mitochondrial protein were observed. The results support the view that changes other than fatty acid unsaturation are involved in the abrupt change in mitochondrial membrane properties at low temperature.     

Hexose metabolism in pancreatic islet cells: the coupling between hexose phosphorylation and mitochondrial respiration

The possible relevance of D-glucose phosphorylation by mitochondria-bound hexokinase to the control of respiration was examined in mitochondria prepared from either tumoral pancreatic islet cells (RINm5F line) or normal rat liver. In both systems, ATP generated by mitochondria exposed to ADP and succinate could serve as a substrate for the phosphorylation of D-glucose. However, after exposure to exogenous ADP in the presence of succinate, only mitochondria isolated from RINm5F cells displayed a sizeable increase in O2 consumption in response to a subsequent administration of D-glucose. In this respect, the discrepancy between mitochondria from islet cells and liver, respectively, was found to be attributable to the much lower hexokinase activity, relative to respiratory rate, in liver than in RINm5F cell mitochondria. It is speculated that the coupling between hexose phosphorylation and respiration in islet cells may prime the mitochondria to generate ATP during the early metabolic and secretory response to a rise in extracellular D-glucose concentration.     

Effects of sodium and potassium ions on oxidative phosphorylation in relation to respiratory control by a cell-membrane adenosine triphosphatase

1. A study has been made of the oxygen consumption of kidney homogenates in relation to the ADP concentration as regulated by the cell-membrane adenosine triphosphatase. Stimulation of this enzymic activity by Na(+) and K(+) caused parallel increases in oxygen consumption and ADP concentration. Similarly, inhibition with ouabain caused a parallel fall. The membrane adenosine triphosphatase concerned in active transport therefore appears to regulate respiration through its control of ADP concentration. 2. The respiration of homogenates and mitochondria was also stimulated by K(+) in a way independent of adenosine-triphosphatase activity. It was shown that K(+) facilitates oxidative phosphorylation and the respiratory response to ADP. A K(+) concentration of 25-50mm was needed for maximum oxidative phosphorylation in the presence of physiological concentration of Na(+). Na(+) counteracted K(+) in the effects on mitochondria. It is concluded that K(+) regulates cellular respiration at two structures, one directly in mitochondria, and the second indirectly through control of ADP production at the cell membrane.     

Altered Mitochondrial Function in Canine Ceroid-Lipofuscinosis

The neuronal ceroid-lipofuscinoses (NCL) are a group of autosomal recessively inherited neurodegenerative disorders characterized by progressive dementia, neuronal atrophy, and premature death. The late infantile and juvenile types of NCL show massive accumulation of mitochondrial ATP synthase subunit c protein in both mitochondria and lysosomes. The specific accumulation of this mitochondrial protein suggests that mitochondrial function may be impaired in the NCL diseases. Therefore, a study was conducted to determine whether oxidative phosphorylation is altered in liver mitochondria from English setters with NCL, an animal model in which there is also massive accumulation of the subunit c protein. The ADP/O ratios were significantly depressed in affected and carrier dogs, suggesting that the disease mutation led to a partial uncoupling of oxidative phosphorylation. On the other hand, ADP-stimulated respiration rates were higher than normal in both carriers and affected dogs. The increased respiration rates were highest in the carriers, and may reflect a compensatory response to the reduced efficiency of oxidative phosphorylation. Accompanying the increased respiration rates were elevations in mitochondrial ADP content with the elevation being greater in the carriers than in the affected dogs. This suggests that the increased respiration rates may be due, at least in part, to enhanced ADP uptake by the mitochondria. In the carriers, the enhanced respiration rate may be sufficient to offset the reduced efficiency of oxidative phosphorylation. In the affected animals, which had lower respiration rates than the carriers, the enhanced respiration rates may not be sufficient to offset the reduced efficiency of oxidative phosphorylation. Impaired mitochondrial function may therefore contribute to the disease pathology.     

Mechanism of oxidative phosphorylation. I. Role of the respiratory chain]

Mitochondria of white rat brain increased the respiration on succinate in response to ADP addition; in the presence of after NADH the respiration remained unchanged or decreased ofter addition ADP. When organelles were suspended in water distilled in the concentration of 3 mg of protein/ml and kept at melting ice temperature for 24 hours the response of mitochondria to ADP was not changed. Stechiometric relation between the number of electron of the oxidized substrate and absorbed by oxygen depended on ADP during succinate oxidation and did not change on NADH. ADP phosphorylation is suggested to proceed on the stage of the substrate dehydrogenation, rather than on the cytochrome part of the respiratory chain.     

Inhibition of oxidative phosphorylation in ascites tumor mitochondria and cells by intramitochondrial Ca2+

Accumulation of Ca2+ (+ phosphate) by respiring mitochondria from Ehrlich ascites or AS30-D hepatoma tumor cells inhibits subsequent phosphorylating respiration in response to ADP. The respiratory chain is still functional since a proton-conducting uncoupler produces a normal stimulation of electron transport. The inhibition of phosphorylating respiration is caused by intramitochondrial Ca2+ (+ phosphate). ATP + Mg2+ together, but not singly, prevents the inhibitory action of Ca2+. Neither AMP, GTP, GDP, nor any other nucleoside 5'-triphosphate or 5'-diphosphate could replace ATP in this effect. Phosphorylating respiration on NAD(NADP)-linked substrates was much more susceptible to the inhibitory effect of intramitochondrial Ca2+ than succinate-linked respiration. Significant inhibition of oxidative phosphorylation is given by the endogenous Ca2+ present in freshly isolated tumor mitochondria. The phosphorylating respiration of permeabilized Ehrlich ascites tumor cells is also inhibited by Ca2+ accumulated by the mitochondria in situ. Possible causes of the Ca2+-induced inhibition of oxidative phosphorylation are considered.     

大鼠心肌整体缺血及离体再灌注致生物膜的损伤作用

目的和方法：利用整体大鼠异丙肾上腺素损伤（ISO）和离体大鼠全心停灌／再灌（I／R）两种模型,观察了心肌缺血和缺血／再灌注对心肌生物膜－线粒体膜及肌纤维膜损伤的影响。结果：ISO（5mg/kg,皮下注射）和I／R（20min/20min)可导致大鼠心脏生物膜产生严重损伤,表现为心肌线粒体脂质过氧化产物明显增加,线粒体磷脂酶A2（PLA2）激活,从而导致线粒体膜磷脂（PL）含量减少,磷脂分解产物游离脂肪酸（FFA）增加,膜脂流动性（LFU）降低,线粒体Ca^2 -ATPase及肌纤维膜Na^ ,K^ -ATPase活性降低,线粒体呼吸功能降低、呼吸链氧化磷酸化解偶联,高能磷酸化合物生成减少。结论：整体ISO和离体I／R可导致大鼠心肌线粒体、肌纤维膜结构和功能损伤。     

Protamine inhibition of the oxidative phosphorylation in intact, cytochrome c-depleted and restored mitochondria.

On the basis of polarographic data it is shown that protamine has a biphasic effect on the respiration of intact mitochondria. At lower protamine concentrations respiration is stimulated and this combined with a decrease of the respiratory control index; at higher ones respiration is inhibited and respiratory control is lost. In cytochrome c-depleted and restored mitochondria protamine effect on oxidative phosphorylation is only inhibitory. Increasing cytochrome c concentrations restore respiration in protamine-treated cytochrome c depleted mitochondria but not the respiratory control. Binding of cytochrome c to mitochondria is studied by determining from Scatchard plots the number of high affinity binding sites (n) and their stability constants (K). In absence of protamine in intact mitochondria n = 2.7 and K = 4.67-10(6) M-1; in cotochrome c depleted mitochondria n = 4.7 and K = 5.16-10(6) M-1. In both types of mitochondria protamine decreases significantly n as well as K. These data show that protamine may affect oxidative phosphorylation by causing desorption of cytochrome c from the inner mitochondrial membrane.     

Temperature response of oxygen uptake in brain mitochondria from normal and ischemic rats

Mitochondria isolated from rat brains following 30 min of complete (decapitation) ischemia showed a 3-fold increase in free fatty acid content, but no significant decreases in the total fatty acid or phospholipid content.This free fatty acid increase was associated with an altered mitochondrial function: a 50% inhibition of state 3 (+ ADP) respiration and a decrease in the respiratory control ratio from 5.5 to 3 to 24°C. The P:O ratio remained unchanged at 3, and there was no increase in stage 4 respiration. When glutamate and malate supported respiration was determined as a function of temperature in control mitochondria, the resulting Arrhenius plot of the state 3 respiration was biphasic with a transition temperature around 30°C, while ischemic mitochondria exhibited a linear Arrhenius plot with energy of activation (approximately 10 kcal/mol) similar to that of control mitochondria below the transition temperature.The difference in temperature response between control and ischemic mitochondria reflects a change in mitochondrial lipid composition, and is therefore a functional manifestation of the altered cerebral lipid composition commonly observed during ischemia.     

Changes in the stimulation of mitochondrial respiration by adrenaline depending upon the dose

Effects of low and high 25 and 100 micrograms per 100 g of body weight doses of adrenaline on respiration and oxidative phosphorylation in rat liver mitochondria are compared. The high dose of adrenaline is shown to decrease activation of respiration and phosphorylation typical of the low doses. This decrease is caused by inhibition of succinate dehydrogenase and is accompanied by uncoupling of respiration and phosphorylation in mitochondria.     

Mitochondrial metabolic suppression and reactive oxygen species production in liver and skeletal muscle of hibernating thirteen-lined ground squirrels

During hibernation, animals cycle between periods of torpor, during which body temperature (T(b)) and metabolic rate (MR) are suppressed for days, and interbout euthermia (IBE), during which T(b) and MR return to resting levels for several hours. In this study, we measured respiration rates, membrane potentials, and reactive oxygen species (ROS) production of liver and skeletal muscle mitochondria isolated from ground squirrels (Ictidomys tridecemlineatus) during torpor and IBE to determine how mitochondrial metabolism is suppressed during torpor and how this suppression affects oxidative stress. In liver and skeletal muscle, state 3 respiration measured at 37°C with succinate was 70% and 30% lower, respectively, during torpor. In liver, this suppression was achieved largely via inhibition of substrate oxidation, likely at succinate dehydrogenase. In both tissues, respiration by torpid mitochondria further declined up to 88% when mitochondria were cooled to 10°C, close to torpid T(b). In liver, this passive thermal effect on respiration rate reflected reduced activity of all components of oxidative phosphorylation (substrate oxidation, phosphorylation, and proton leak). With glutamate + malate and succinate, mitochondrial free radical leak (FRL; proportion of electrons leading to ROS production) was higher in torpor than IBE, but only in liver. With succinate, higher FRL likely resulted from increased reduction state of complex III during torpor. With glutamate + malate, higher FRL resulted from active suppression of complex I ROS production during IBE, which may limit ROS production during arousal. In both tissues, ROS production and FRL declined with temperature, suggesting ROS production is also reduced during torpor by passive thermal effects.     

Temperature sensitivity of cardiac mitochondria in intertidal and subtidal triplefin fishes

The heart is acutely sensitive to temperature in aquatic ectotherms and appears to fail before any other organ as the thermal maximum is reached, although the exact cause of this failure remains unknown. The heart is highly aerobic and therefore dependent on mitochondrial oxidative phosphorylation (OXPHOS) to meet energy requirements, but the role of cardiac mitochondria in limiting heart function at high temperatures remains unclear. We used permeabilised ventricle fibres to explore heart mitochondrial function in situ in three closely related species of small New Zealand triplefin fishes in response to temperature. We compared this to measures of whole animal respiration rates and critical oxygen tensions in these fishes. Bellapiscis medius, an intertidal species, had the greatest tolerance to hypoxia at higher temperatures and had more efficient OXPHOS at 30°C than the two subtidal species Forsterygion varium and F. malcolmi. B. medius also displayed the highest cytochrome c oxidase flux, which may in part explain how B. medius tolerates higher temperatures and hypoxia. Triplefin heart mitochondria exhibit decreased coupling to phosphorylation with increasing temperature. This most likely impairs ATP supply to the heart at elevated temperatures, potentially contributing to heart failure at ecologically relevant temperatures.     

Effect of thyroxin on the functional state of the respiratory chain in liver mitochondria of the carp Cyprinus carpio during acclimatization to changes in water temperature

It has been demonstrated that oxidative phosphorylation in liver mitochondria of the carps which were kept within a week at 5 and 25 degrees C remains unaffected by the addition of 0.5 micron thyroxin to the incubation medium. Addition of thyroxin (0.5 micron) to mitochondrial suspension prepared from the liver of carps acclimated within a week at 20 and especially 25 degrees C, resulted in uncoupling of respiration and phosphorylation. Daily injections of thyroxin within a week (2 mu kg per 1 g of body weight) to carps at 20 and 25 degrees C resulted in the increase of the rate of non-phosphorylating oxidation and the decrease of oxidative phosphorylation in liver mitochondria. The increase of temperature of water from 5 to 30 degrees C decreases triiodthyronine content of the blood serum in the carp.     

The effect of low concentrations of sodium nitrites and nitrates on respiration and oxidative phosphorylation in rat liver mitochondria]

Nitrite incubation in mitochondria and nitrate intoxication of rats have been studied for their effect on aerobic energetic processes in the liver. Sodium nitrite in concentration of 2 mg/l causes an inhibition of ADP-stimulated respiration and provides uncoupling processes of oxidative phosphorylation and respiration in mitochondria, when adding succinate as a substrate. Low doses of nitrate in vivo promote oxygen economization in mitochondria. Intoxication of rats with nitrate in a dose of 50 mg/l for 30 days induces a decrease of the respiration rate after ADP-phosphorylation and an increase of the coefficient of oxidative phosphorylation efficiency (ADP/O). Intraperitoneal administration of adrenalin in a dose of 25 micrograms/100 g to rats after 30-day nitrate intoxication in a concentration of 10 mg/l induces no typical increase of ADP-stimulated respiration and rate of oxidative phosphorylation and succinate oxidation.     

Feedback Regulation and Time Hierarchy of Oxidative Phosphorylation in Cardiac Mitochondria

To determine how oxidative ATP synthesis is regulated in the heart, the responses of cardiac mitochondria oxidizing pyruvate to alterations in [ATP], [ADP], and inorganic phosphate ([P_i]) were characterized over a range of steady-state levels of extramitochondrial [ATP], [ADP], and [P_i]. Evolution of the steady states of the measured variables with the flux of respiration shows that: (1) a higher phosphorylation potential is achieved by mitochondria at higher [P_i] for a given flux of respiration; (2) the time hierarchy of oxidative phosphorylation is given by phosphorylation subsystem, electron transport chain, and substrate dehydrogenation subsystems listed in increasing order of their response times; (3) the matrix ATP hydrolysis mass action ratio [ADP] × [P_i]/[ATP] provides feedback to the substrate dehydrogenation flux over the entire range of respiratory flux examined in this study; and finally, (4) contrary to previous models of regulation of oxidative phosphorylation, [P_i] does not modulate the activity of complex III.     

Top-down control analysis of the effect of temperature on ectotherm oxidative phosphorylation

Top-down control and elasticity analysis was conducted on mitochondria isolated from the midgut of the tobacco hornworm (Manduca sexta) to assess how temperature affects oxidative phosphorylation in a eurythermic ectotherm. Oxygen consumption and protonmotive force (measured as membrane potential in the presence of nigericin) were monitored at 15, 25, and 35 degrees C. State 4 respiration displayed a Q(10) of 2.4-2.7 when measured over two temperature ranges (15-25 degrees C and 25-35 degrees C). In state 3, the Q(10)s for respiration were 2.0 and 1.7 for the lower and higher temperature ranges, respectively. The kinetic responses (oxygen consumption) of the substrate oxidation system, proton leak, and phosphorylation system increased as temperature rose, although the proton leak and substrate oxidation system showed the greatest thermal sensitivity. Whereas there were temperature-induced changes in the activities of the oxidative phosphorylation subsystems, there was no change in the state 4 membrane potential and little change in the state 3 membrane potential. Top-down control analysis revealed that control over respiration did not change with temperature. In state 4, control of respiration was shared nearly equally by the proton leak and the substrate oxidation system, whereas in state 3 the substrate oxidation system exerted over 90% of the control over respiration. The proton leak and phosphorylation system account for <10% of the temperature-induced change in the state 3 respiration rate. Therefore, when the temperature is changed, the state 3 respiration rate is altered primarily because of temperature's effect on the substrate oxidation system.     

Oxidative phosphorylation in rat liver mitochondria: influence of physical parameters.

Effects of pH, temperature, ionic strength and osmotic pressure on various respiratory states and indices of oxidative phosphorylation in well coupled rat liver mitochondria have been studied. It appears that temperature and osmotic pressure are the most important physical variables, whereas ionic strength and pH were devoid of any significant influence on oxidative phosphorylation. Thus any model for oxidative phosphorylation must critically account for the differential osmotic sensitivity of respiration as well as the curious fact that ADP/O ratio increases as temperature decreases.