EC:2.3.3.1 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.3.3.1 (citrate synthase)
4,488 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Chronic stimulation of rat fast-twitch muscle increased the content of both fatty acid-binding protein (FABP) and myoglobin. The increases in FABP, which reached values close to that of cardiac muscle, exceeded those in myoglobin and those in citrate synthase and 3-hydroxyacyl-CoA dehydrogenase activities.
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PMID:Electrostimulation-induced increases in fatty acid-binding protein and myoglobin in rat fast-twitch muscle and comparison with tissue levels in heart. 292 22

The purpose of this study was to determine whether thyroid hormone could directly affect the phenotypic expression of two isozymic systems [lactate dehydrogenase (LDH) and myosin] and the energy transducing potential of cultured neonatal heart cells. In addition we determined if these biochemical systems developed in culture as they normally do during in vivo post-natal development. Cells were maintained for 14 days in culture medium containing 10% horse serum and Earle's salts. Experimental cultures were supplemented with 10 nmol/l 3,3',5-triiodo-L-thyronine (T3). Hearts used to study in vivo development were excised from rats at the ages of 2 and 14 days post-natal to correspond with the time of isolating and harvesting the cultured heart cells, respectively. Adult hearts were used to represent the final developmental stage. Cultured cardiomyocytes without T3 administered to the culture medium showed no change in the isozymic profiles (myosin and LDH) or in metabolic potential during the 2 week culture period. The T3 treated cultures showed a complete shift to the V1 myosin isozyme. The glycolytic and aerobic metabolic potential [i.e., phosphofructokinase (PFK) and citrate synthase (CS) activities] and the LDH isozyme distribution were unaltered by T3 treatment. During in vivo development a shift toward the V1 myosin and H-LDH isozymes along with an increase in aerobic metabolism occurred in the rat heart. These findings indicate that the development of these selected biochemical systems in cultured cardiac myocytes does not result from an intrinsic myogenetic program and thus must be regulated in vivo by epigenetic factor(s). These results show that T3 has the potential to be the prime determinant of the phenotypic expression of the myosin isoforms, but does not have the potential to be the sole determinant for the expression of the LDH isozymes or the glycolytic (PFK) and aerobic (CS) capacities of cardiac muscle cells.
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PMID:The effects of triiodothyronine on cultured neonatal rat cardiac myocytes. 297 10

The thermogenic response to catecholamines, i.e., regulatory nonshivering thermogenesis (NST), is significantly reduced in dystrophic hamsters (BIO 14.6) compared with age-matched normals. The possibility that this reduction reflects, in part, lower levels of enzymes in those tissues implicated in NST has been examined by assaying citrate synthase (CS), beta-hydroxyacyl CoA dehydrogenase (HOAD), and phosphofructokinase (PFK), enzymes whose activity reflect the potential flux of substrates through the tricarboxylic acid cycle, beta-oxidation, and glycolysis, respectively. Each enzyme was assayed in brown fat, heart, gastrocnemius, and semitendinosus of 3-mo-old normal (n = 15) and dystrophic (n = 18) hamsters. Brown fat masses from interscapular, cervical, and scapular-axillary regions of dystrophics averaged only 50% those of normals (424 vs. 890 mg). Additionally, markers of aerobic metabolism (CS and HOAD) were significantly reduced in the brown fat from dystrophic animals. (CS activities averaged 59% of normal, whereas HOAD activities averaged 75% of normal). In dystrophic animals CS and HOAD levels were similar to those of normals in cardiac tissue but were significantly elevated in skeletal muscle samples. Tissue PFK activities were reduced only in cardiac tissue of the more affected dystrophics. Thus decreased NST capacity in dystrophic hamsters is accompanied by reduced masses and CS values in brown fat but not by decreases in the aerobic markers in skeletal or cardiac muscle.
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PMID:Metabolic organization of muscle and brown fat of normal and dystrophic hamsters. 621 87

The activities of several lysosomal enzymes were assayed in control and in exercise-hypertrophied cardiac muscle of mice (Mus musculus). The repeated running program increased the activity of beta-glucuronidase (16.1%) in mouse cardiac muscle. Decreased activities of beta-N-acetylglucosaminidase (10.8%), acid ribonuclease (10.7%), and arylsulphatase (14.2%) were observed in the hypertrophied myocardium. The activities of acid deoxyribonuclease, cathepsin C, cathepsin D, and p-nitrophenylphosphatase as well as the activities of citrate synthase and cytochrome c oxidase, mitochondrial enzymes, were unaffected in cardiac muscle. We suggest that lysosomal enzyme responses are selective and highly different in physiologically and pathologically induced cardiac hypertrophies.
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PMID:Changes in lysosomal enzyme activities in exercise-induced cardiac hypertrophy of mice. 622 47

We studied the effects of running-training, heavy exercise and termination of training on the heart weight, the ratio heart to body weight and the cardiac muscle activities of actomyosin ATPase, citrate synthase, succinate dehydrogenase, cytochrome c oxidase, malate dehydrogenase, adenylate kinase and beta-glucuronidase with adult male NMRI-mice. Stable hypertrophy (6-7%), estimated by the ratio heart or ventricle weight to body weight, was achieved by 28 exercises and it was dependent on the running speed (20 vs. 25 m X min-1). The withdrawal of training for 5-61 days did not permanently decrease the heart weight or the heart to body weight ratio to the level of sedentary controls. The activity of enzymes of energy metabolism or actomyosin ATPase were not affected by training, heavy exercise or terminated training. beta-glucuronidase activity slightly (20-25%) increased in the trained animals and remained at a higher level during the period of terminated training. The results suggest that the capacity for aerobic metabolism of normal mice heart is sufficient to meet the enhanced demand for ATP imposed by running-training and that the heart enlargement occurs in equal proportions with the enzymatic potential of the cardiac tissue.
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PMID:Selected enzyme activities in mouse cardiac muscle during training and terminated training. 623 64

Acid proteolytic capacity in mouse cardiac muscle and in predominantly white (distal head of m. vastus lateralis) or predominantly red (proximal red heads of m. vastus lateralis, m. v. medialis, and m. v. intermedius) skeletal muscle was estimated 5 days after 3 h, 6 h or 9 h prolonged running at a speed of 13.5 m/min. The activities of acid protease and beta-glucuronidase together with the rate of acid autolysis considerably increased in both skeletal muscle types, especially in red muscle, but did not increase in cardiac muscle. Acid proteolytic capacity and beta-glucuronidase activity increased in relation to the duration of running. Protein content and oxidative capacity (the activities of citrate synthase and malate dehydrogenase) decreased in red skeletal muscle after 6 h and 9 h running. In white muscle only protein content slightly decreased after 9 h running. No corresponding changes were observed in cardiac muscle. Histopathological changes were traced in mixed skeletal muscle (m. rectus femoris). Necrotic lesions were observed in the red superficial area of m. rectus femoris after 6 h and, in particular, after 9 h running. The results show that prolonged submaximal running also produces lethal and sublethal skeletal muscle fibre injuries, as well as exhaustive exercise or temporary ischaemia as reported earlier. It is suggested that sublethal injuries precede lethal ones and that acid proteolytic capacity increases especially in the sublethally injured muscle fibres.
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PMID:Acid proteolytic capacity in mouse cardiac and skeletal muscles after prolonged submaximal exercise. 719 62

We examined skeletal and cardiac muscle responses of mature (8 mo) and old (23 mo) male Fischer 344 rats to 14 days of hindlimb suspension. Hexokinase (HK) and citrate synthase (CS) activities and GLUT-4 glucose transporter protein level, which are coregulated in many instances of altered neuromuscular activity, were analyzed in soleus (Sol), plantaris (PI), tibialis anterior (TA), extensor digitorum longus (EDL), and left ventricle. Protein content was significantly (P < 0.05) lower in all four hindlimb muscles after suspension compared with controls in both mature (21-44%) and old (17-43%) rats. Old rats exhibited significantly lower CS activities than mature rats for the Sol, Pl, and TA. HK activities were significantly lower in the old rats for the Pl (19%) and TA (33%), and GLUT-4 levels were lower in the old rats for the TA (38%) and EDL (24%) compared with the mature rats. Old age was also associated with a decrease in CS activity (12%) and an increase in HK activity (14%) in cardiac muscle. CS activities were lower in the Sol (20%) and EDL (18%) muscles from mature suspended rats and in the Sol (25%), Pl (27%), and EDL (25%) muscles from old suspended rats compared with corresponding controls. However, suspension was associated with significantly higher HK activities for all four hindlimb muscles examined, in both old (16-57%) and mature (10-43%) rats, and higher GLUT-4 concentrations in the TA muscles of the old rats (68%) but not the mature rats. These results indicate that old age is associated with decreased CS and HK activities and GLUT-4 protein concentration for several rat hindlimb muscles, and these variables are not coregulated during suspension. Finally, old rat skeletal muscle appears to respond to suspension to a similar or greater degree than mature rat muscle responds.
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PMID:Muscle adaptations to hindlimb suspension in mature and old Fischer 344 rats. 917 53

High-intensity treadmill exercise increases the expression of a cardioprotective, inducible 72-kDa stress protein (SP72) in cardiac muscle. This investigation examined whether voluntary free wheel exercise training would be sufficient to confer a similar response. Male Sprague-Dawley rats were randomly assigned to either treadmill (TM-Tr) or free wheel (FW-Tr) training groups. By the end of the 8-wk training period, TM-Tr animals ran 1 h/day, 5 days/wk up a 10% grade, covering a distance of 8,282 m/wk. FW-Tr rats ran, on average, 5,300 m/wk, with one-third of the animals covering distances similar to those for the TM-Tr group. At the time of death, hearts of trained and caged sedentary control (Sed) animals were divided into left (LV) and right (RV) ventricles. Citrate synthase activity and the relative immunoblot contents of SP72, SP73 (the constitutive isoform of the SP70 family), and a 75-kDa mitochondrial chaperone (SP75) were subsequently determined. LV and RV did not differ on any measure, and SP73, SP75, and citrate synthase were not affected by training. Cardiac SP72 levels were elevated over fourfold in both ventricles of TM-Tr compared with RV of FW-Sed rats. Despite the animals having run a similar total distance, cardiac SP72 content in FW-Tr rats was not different from that in Sed animals. These data indicate that voluntary exercise training is insufficient to elicit an elevation of SP72 in rat heart and suggest that exercise intensity may be a critical factor in evoking the cardioprotective SP72 response.
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PMID:Differential expression of stress proteins in rat myocardium after free wheel or treadmill run training. 1023 37

(1) Malonyl-CoA is thought to play a signalling role in fuel-selection in cardiac muscle, but the rate at which the concentration of this potential signal can be changed has not previously been investigated. (2) Rapid changes in cellular malonyl-CoA could be observed when rat cardiac myocytes were incubated in glucose-free medium followed by re-addition of 5 mM glucose, or when cells were transferred from a medium containing glucose to a glucose-free medium. On addition of glucose, malonyl-CoA increased by 62% to a new steady-state level, at a rate of at least 0.4 nmol/g dry wt. per min. The half-time of this change was less than 3 min. After removal of glucose the malonyl-CoA content was estimated to decline by 0.43-0.55 nmol/g dry wt. per min. (3) Malonyl-CoA decarboxylase (MDC) is a possible route for disposal of malonyl-CoA. No evidence was obtained for a cytosolic activity of MDC in rat heart where most of the activity was found in the mitochondrial fraction. MDC in the mitochondrial matrix was not accessible to extramitochondrial malonyl-CoA. However, approx. 16% of the MDC activity in mitochondria was overt, in a manner that could not be explained by mitochondrial leakage. It is suggested that this, as yet uncharacterized, overt MDC activity could provide a route for disposal of cytosolic malonyl-CoA in the heart. (4) No activity of the condensing enzyme for the fatty acid elongation system could be detected in any heart subcellular fraction using two assay systems. A previous suggestion [Awan and Saggerson (1993) Biochem. J. 295, 61-66] that this could provide a route for disposal of cytosolic malonyl-CoA in heart should therefore be abandoned.
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PMID:Malonyl-CoA metabolism in cardiac myocytes. 1092 26

Little information is available regarding the influence of the intensity of endurance training over biochemical profiles in cardiac muscle. We assessed the effect of running training at two different intensities on cardiac myosin isozyme composition in rats. Male Sprague-Dawley rats (4 weeks old) were divided into four groups: sedentary control (SC), trained at 20 m/min (T20), trained at 40 m/min (T40), and weight-matched sedentary control (WMSC) groups. The T20 and T40 group rats were trained by treadmill running for 60 min/d, 5 d/week at 20 or 40 m/min, respectively, for 11 to 12 weeks. In both groups the left ventricle was significantly heavier than in WMSC animals. The ratio of left ventricle weight to body weight was significantly greater in T40 rats than in either the untrained (SC and WMSC) or trained T20 rats. Thus the extent of exercise-induced cardiac hypertrophy appears to be influenced by the intensity of running training. However, neither of the training programs (1) induced a change in cardiac myosin isozyme composition or (2) had any effect on myocardial succinate dehydrogenase or citrate synthase activity. These results suggest that although the intensity of running training may play an important role in cardiac morphological adaptation, it does not modulate the cardiac biochemical adaptation to running training.
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PMID:Lack of effect of running training at two intensities on cardiac myosin isozyme composition in rats. 1117 53

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