Effect of experimentally induced thyrotoxicosis on oxidative energy metabolism in rat heart mitochondria

Treatment of rats with T₃ resulted in a significant decrease in body weight, while the heart weight increased. T₄ treatment had less marked effect on body weights but resulted in decreased heart weights. Serum T₄ levels decreased significantly with simultaneous increase of T₃ level following T₃ treatment, whereas with T₄ treatment, levels of both T₄ and T₃ increased in the serum. Low doses of T₃ (0.5 μg ) caused decrease in mitochondrial protein content while high dose of T₄ (1 μg), caused significant increase in mitochondrial mass. The state 3 respiration rates were significantly depressed following T₃ and T₄ treatments, in a substrate specific manner with the effects being more pronounced with T₃; these responses with T₄ were dose-dependent for succinate and ascorbate + N,N,N′,N′-tetramethyl-p-phenylenedíamme. State 4 respiration rates also exhibited similar corresponding changes. ADP/O ratios were not changed but ADP-phosphorylation rates were decreased significantly particularly so with the T₃-treated animals. Treatment with T₃ also resulted in lowering of intramitochondrial cytochrome contents. Similar effects were seen also with higher doses of T₄. The results thus indicate that T_3- and T_4- thyrotoxicosis results in impaired energy metabolism in heart mitochondria.     

Regulation of energy metabolism in liver

Energy metabolism in liver has to cope with the special tasks of this organ in intermediary metabolism. Main ATP-generating processes in the liver cell are the respiratory chain and glycolysis, whereas main ATP-consuming processes are gluconeogenesis, urea synthesis, protein synthesis, ATPases and mitochondrial proton leak. Mitochondrial respiratory chain in the intact liver cell is subject to control mainly by substrate (hydrogen donors, ADP, oxygen) transport and supply and proton leak/slip. Whereas hormonal control is mainly on substrate supply to mitochondria, proton leak/slip is supposed to play an important role in the modulation of the efficiency of oxidative phosphorylation.     

The subunit proportions and kinetic properties of 6-phosphofructo-1-kinase isozymes from rat heart atria and ventricle progressively change during aging

Relative to 2–3 month rats, total 6-phosphofructo-1-kinase (PFK) activity in heart atria from 12 month rats declined 31%; but, by 24 months it was decreased by only 13%. PFK activities from 12 and 24 month ventricles relative to the 2–3 month rat were decreased by 40% and 30%, respectively. This change in PFK activity in each heart region was associated with alterations of subunit composition. In heart atria from 12 and 24 month rats when compared to 3 month rats, the levels of L-type subunit were not significantly different; but the levels of the M-type subunit were decreased by 43% and 38%, respectively. With respect to levels in 2–3 month atria, the C-type subunit in 12 month atria decreased by 27%; and at 24 months it increased by 31%. Making the same comparison for the heart ventricle at 12 and 24 months, L-type subunit decreased by 30% and 24% respectively; M-type subunit decreased by approximately 47%; and the C-type subunit increased 1.9 and 4.7 fold, respectively. These age-related changes of subunit composition in atrial and ventricular PFK isozyme pools led to changes in their kinetic and regulatory properties suggesting that the aged rat could exhibit a diminished capacity to produce ATP from glucose.     

昼夜节律与能量代谢

地球上大多数生物存在内源性的昼夜节律生物钟,它使得生物个体能够预知环境中由于地球自转产生的周期性昼夜变化。这种预知性使得生物个体的内在生理节律与周围环境的变化周期保持一致,从而能够更有效地从周围环境中摄取能量,在体内更高效地利用能量,亦即更好的适应环境以获得进化上的优势。生物钟能够广泛调控哺乳动物的睡眠、进食和代谢等多个方面的行为和生理功能,生物钟的破坏与多种代谢疾病相关;同时代谢过程和进食行为也能反过来调控生物钟。近年来对生物钟的不断研究加深了人们对肥胖和糖尿病等代谢疾病的理解,为这些疾病的治疗提供了新的思路和方法。本文主要综述哺乳动物生物钟与能量代谢之间的关系及研究进展。     

Physiological relevance of the changing subunit composition and regulatory properties of the 6-phosphofructo-1-kinase isozyme pools during heart and muscle development

During postnatal development, the subunit compositions of the 6-phosphofructo-l-kinase isozyme pools of heart and skeletal muscle are known to change. The isozyme pools from fetal muscle were composed of the L-type (60%), and M-type (36%) and C-type (4%) subunits and the isozymes from fetal and early neonatal heart contain nearly equal amounts of all three subunits. During postnatal development of both tissues, the proportion of the M-type subunit increases until it is the only type present in adult muscle and the major subunit in adult heart (7507o). The isozyme pool from fetal muscle exhibit a decreased affinity for fructose-6-P and a greater susceptibility to ATP inhibition compared to the M-rich isozymes which are subsequently present. The isozyme pools from fetal and early neonatal heart, if compared to the M-rich isozymes which are present later during heart development and to the fetal muscle isozymes, exhibited the least affinity for fructose-6-P and the greatest susceptibility to ATP inhibition. Comparison of the isozyme pools containing little or no C-type subunit with those from fetal and early neonatal heart clearly indicates that the presence of substantial levels of the C-type subunit imposed a decreased ability for fructose-2,6-P₂ to both lower affinity for fructose-6-P and antagonize sensitivity to ATP inhibition. Although still not thoroughly appreciated, it appears that the changing nature of the isozyme pools in these tissues permits regulation of glucose metabolism in a manner which allows efficient utilization of nutritional opportunities and which adequately meets the energy requirements of each tissue at different stages of development.Abbreviations PFK 6-phosphofructo-l-kinase - fructose-6-P D-fructose-6-phosphate - fr-t_ose-2,6-P₂ D-fructose-2,6-bisphosphate     

Treatment with dehydroepiandrosterone (DHEA) stimulates oxidative energy metabolism in the liver mitochondria from developing rats

Effects of treatment with DHEA (0.2 mg or 1.0 mg / kg body weight for 7 days) on oxidative energy metabolism on liver mitochondria from developing and young adult rats were examined. Treatment with DHEA resulted in a progressive dose-dependent increase in the liver weights of the developing animals without change in the body weight. In the young adult rats treatment with 1.0 mg DHEA showed increase only in the body weight. Treatment with DHEA stimulated state 3 and state 4~respiration rates in developing as well as young adult rats in dose-dependent manner with all the substrates used; magnitude of stimulation was age-dependent. In young adults the extent of simulation of state 3 respiration rates declined at higher dose (1.0~mg) of DHEA with glutamate and succinate as substrates. Stimulation of state 3 respiration rates was accompanied by increase in contents of cytochrome aa_3, b and c + c₁ and stimulation of ATPase and dehydrogenases activities in dose- and age-dependent manner.     

Studies of regulatory metabolism in Moniezia expansa: the role of phosphoenolpyruvate carboxykinase.

Phosphoenolpyruvate carboxykinase (PEPCK) from M. expansa has been partially purified and its behaviour in a range of different assay conditions has been determined. Different PEPCK's were found in the cytosol and mitochondria. Some kinetic parameters for each are presented. Both enzymes are activated by Mn²⁺; cytosolic PEPCK is also activated by Mg²⁺. The enzymes have pH optima in the range 6·4–7·0. They do not differ with respect to their apparent affinities for inosine and guanosine diphosphates, but the latter allows higher maximal activity. Little activity is observed with adenosine diphosphate. Adenosine and inosine triphosphates exert weak inhibitory effects on the Mn²⁺ activated enzymes; a much strongsr inhibition is exerted on the cytosolic enzyme when activated by Mg²⁺. A number of non-nucleotide compounds were tested for possible inhibitory effects with no success. The forward and back reactions catalyzed by PEPCK proceed at similar rates, suggesting that the enzyme may be readily raversible in vivo.     

利用核磁共振同时观测大鼠心室内压参数与能量代谢

本文介绍一种在核磁共振（ｎｕｃｌｅａｒ ｍａｇｎｅｔｉｃ ｒｅｓｏｎａｎｃｅ,ＮＭＲ）谱仪上对大鼠主室内压参数与能量代谢同时测定的技术。该方法采用离体等容大鼠心功能监测系统测量和分析心脏的心室内压参数,通过测定心脏的磷－３１核磁共振（＾３１Ｐ ＮＭＲ）谱观测心肌组织的能量代谢状态。     

Circadian rhythm disorders and dynamic changes of energy metabolism in rat heart muscle cells

The functional states of pro- and antioxidant systems in blood and heart muscle cells in rats with long-term emotional stress have been studied. It has been shown that daily rhythm disorders produce psycho-emotional stress in animals and that, this is accompanied by quantitative changes in physiological parameters and hormones in the blood. In the present study, it was observed that such stress increased lipid peroxidation in blood and heart muscle cells. Also, activities of antioxidant enzymes, superoxide dismutase, and catalase were diminished, indicating deterioration of the antioxidant system. In addition, there were decreased activities of mitochondrial enzymes participating in energy metabolism, indicating decreased energy levels in heart muscle cells. These results suggest the likelihood that emotional stress is a key factor that can cause a whole range of diseases of the cardiovascular system.     

Proteomic analysis of mitochondria reveals a metabolic switch from fatty acid oxidation to glycolysis in the failing heart

This work characterizes the mitochondrial proteomic profile in the failing heart and elucidates the molecular basis of mitochondria in heart failure. Heart failure was induced in rats by myocardial infarction, and mitochondria were isolated from hearts by differential centrifugation. Using two-dimen- sional gel electrophoresis and matrix-assisted laser desorption/ionization-time of flight mass spectrometry, a system biology approach was employed to investigate differences in mitochondrial proteins between normal and failing hearts. Mass spectrometry identified 27 proteins differentially expressed that involved in energy metabolism. Among those, the up-regulated proteins included tricarboxylic acid cycle enzymes and pyruvate dehydrogenase complex subunits while the down-regulated proteins were involved in fatty acid oxidation and the OXPHOS complex. These results suggest a substantial metabolic switch from free fatty acid oxidation to glycolysis in heart failure and provide molecular evidence for alterations in the structural and functional parameters of mitochondria that may contribute to cardiac dysfunction during ischemic injury.     

Impairment of glucose metabolism and energy transfer in the hypertriglyceridemic rat heart

The metabolic pathways involved in ATP production in hypertriglyceridemic rat hearts were evaluated. Hearts from male Wistar rats with sugar-induced hypertriglyceridemia were perfused in an isolated organ system. Mechanical performance, oxygen uptake and beat rate were evaluated under perfusion with different oxidizable substrates. Age- and weight-matched animals were used as control. The hypertriglyceridemic (HTG) hearts showed a decrease in the mechanical work and slight diminution in the oxygen uptake when perfused with glucose, pyruvate or lactate. No differences were found when perfused with palmitate, octanoate or -hydroxybutyrate. The glycolytic flux in HTG hearts was 2.4 times lower than in control hearts. Phosphofructokinase-I (PFK-I) was 16% decreased in HTG hearts, whereas pyruvate kinase activity did not change. The increased levels of glucose-6hyphen;phosphate in HTG heart, suggested a flux limitation by the PFK-I. Pyruvate dehydrogenase in its active form (PDHa) diminished as well. The PDHa level in the HTG hearts was restored to control values by dichloroacetate; however, this addition did not significantly improve the mechanical performance. Levels of ATP and phosphocreatine as well as total creatine kinase activity and the MB fraction were significant lower in the HTG hearts perfused with glucose. The data suggested that supply of ATP by glucose oxidation did not suffice to support cardiac work in the HTG hearts; this impairment was exacerbated by the diminution of the creatine kinase system output.     

Glutamate metabolism in cerebral mitochondria after ischemia and post‐ischemic recovery during aging: relationships with brain energy metabolism

Glutamate is involved in cerebral ischemic injury, but its role has not been completely clarified and studies are required to understand how to minimize its detrimental effects, contemporarily boosting the positive ones. In fact, glutamate is not only a neurotransmitter, but primarily a key metabolite for brain bioenergetics. Thus, we investigated the relationships between glutamate and brain energy metabolism in an in vivo model of complete cerebral ischemia of 15 min and during post‐ischemic recovery after 1, 24, 48, 72, and 96 h in 1‐year‐old adult and 2‐year‐old aged rats. The maximum rates (V _max) of glutamate dehydrogenase (GlDH ), glutamate‐oxaloacetate transaminase, and glutamate‐pyruvate transaminase were assayed in somatic mitochondria (FM ) and in intra‐synaptic ‘Light’ mitochondria and intra‐synaptic ‘Heavy’ mitochondria ones purified from cerebral cortex, distinguishing post‐ and pre‐synaptic compartments. During ischemia, none of the enzymes were modified in adult animals. In aged ones, glutamate‐oxaloacetate transaminase was increased in FM and GlDH in intra‐synaptic ‘Heavy’ mitochondria, stimulating glutamate catabolism. During post‐ischemic recovery, FM did not show modifications at both ages while, in intra‐synaptic mitochondria of adult animals, glutamate catabolism was increased after 1 h of recirculation and decreased after 48 and 72 h, whereas it remained decreased up to 96 h in aged rats. These results, with those previously published about Krebs’ cycle and Electron Transport Chain (Villa et al ., [2013] Neurochem. Int . 63, 765–781), demonstrate that: (i) V _max of energy‐linked enzymes are different in the various cerebral mitochondria, which (ii) respond differently to ischemia and post‐ischemic recovery, also (iii) with respect to aging.

     

Alterations in the energy metabolism of the isolated perfused frog heart during calcium depletion and subsequent repletion

Summary The changes in myocardial energy metabolism of isolated perfused Rana ridibunda hearts subjected to prolonged calcium depletion and reperfusion with calcium-containing medium were studied. Calcium-free perfusion resulted in an increase in the concentrations of glucose, glucose-6-phosphate, a-ketoglutarate and malate. The myocardial contents of high-energy phosphates were maintained while concentrations of key amino acids were significantly altered. During the reperfusion period the tissue high-energy phosphate content fell abruptly. A marked increase in glycolytic flux and lactate production was observed. The tissue contents of citric acid cycle intermediates and key amino acids decreased. Examination of the activities of marker enzymes during the calcium-free and reperfusion periods showed that only cytoplasmic enzymes are lost during reperfusion, while the activities of other enzymes remained unchanged. The results suggest that the fluxes of both glycolysis and the citric acid cycle are significantly altered during calcium depletion and following repletion in the amphibian heart. The major characteristics of calcium paradox-induced damage in Rana ridibunda heart are the depletion of high-energy stores, the impairment of mitochondrial oxidative metabolism, and a significant increase in anaerobic metabolism.Abbreviations ADP Adenosine diphosphate - AMP Adenosine monophosphate - ATP Adenosine triphosphate - EDTA Ethylene-diamino-tetraacetic acid - NAD ⁺ Nicotinamide-adeninedinucleotide - NADH Nicotinamide-adenine-dinucleotide (reduced form) - TRA Triethanolamine     

Impaired myocardial autophagy linked to energy metabolism disorders

Autophagy represents an evolutionarily conserved catabolic mechanism that promotes cell survival by releasing energy substrates via degradation of cellular constituents and by eliminating defective organelles under conditions of stress, such as starvation and hypoxia. The link between enhanced autophagy and nutrient deprivation has been well established. For example, chronic myocardial ischemia, a condition of insufficient oxygen and nutrition, activates autophagy to degrade and recycle damaged cellular structures, thereby ameliorating cardiomyocyte injury.     

Impaired myocardial autophagy linked to energy metabolism disorders

Autophagy represents an evolutionarily conserved catabolic mechanism that promotes cell survival by releasing energy substrates via degradation of cellular constituents and by eliminating defective organelles under conditions of stress, such as starvation and hypoxia. The link between enhanced autophagy and nutrient deprivation has been well established. For example, chronic myocardial ischemia, a condition of insufficient oxygen and nutrition, activates autophagy to degrade and recycle damaged cellular structures, thereby ameliorating cardiomyocyte injury.