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)

The beta-adrenergic receptor system not only plays a central role in modulating heart rate and left-ventricular (LV) contractility, but is also involved in the development of heart failure. We have, recently, shown that heart-specific overexpression of the beta(1)-adrenergic receptor in transgenic mice (TG) initially leads to increased contractility, followed by LV hypertrophy and heart failure. Since one feature for all forms of heart failure are characteristic changes in myocardial energy metabolism, we asked whether alterations in energetics are detectable in these mice before signs of LV impairment are present. Myocardial energetics ((31)P NMR spectroscopy) and LV performance were measured simultaneously in isolated perfused hearts at different workloads. LV performance as well as contractile reserve was identical for hearts of 4-month-old TG and wild-type mice. The ratio of phosphocreatine to ATP (1.16 +/- 0.05 vs. 1.46 +/- 0.10) and total creatine content (17.6 +/- 1.2 vs. 22.6 +/- 0.9 mmol/l) were significantly reduced in TG. Furthermore, there was a significant decrease in creatine transporter content (-43%), mitochondrial (-44%) and total creatine kinase (CK) activity (-21%) as well as citrate synthase activity (-25%), indicating impaired oxidative energy generation in TG. In conclusion, these findings of alterations in the CK system, creatine metabolism and mitochondrial proteins in TG hearts prior to the development of LV dysfunction provide further evidence that changes in myocardial energetics play a central role in the deterioration of cardiac function after chronic beta-adrenergic stimulation.
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PMID:Alterations in the myocardial creatine kinase system precede the development of contractile dysfunction in beta(1)-adrenergic receptor transgenic mice. 1268 18

Animal studies have shown that supra-physiological creatine monohydrate (Cr-mH) supplementation for 3 months reduced skeletal muscle creatine transporter (CRT) content. The doses of Cr-mH (1-2 g/kg/day) used in these studies were between 5 and 10 times those usually used in human studies, and it is unclear whether a down-regulation of CRT would occur in humans at the recommended doses of 0.1-0.2 g/kg/day. We measured CRT, and citrate synthase (CS) protein content using Western blotting before and after 2 months of Cr-mH supplementation and weight training in young men (N = 11 Cr-mH (0.125 g/kg/ day); N = 8 placebo). CRT and CS were also measured before and after 4 months of Cr-mH supplementation and weight training in elderly (> 65 years) men and women (N = 14 Cr-mH (0.075 g/kg/day); N = 14 placebo). Finally, CRT mRNA was measured using competitive RT-PCR before and after 8-9 days of Cr-mH loading in young men and women (N = 14, CR-mH (mean = 0.18 g/kg/day); N = 13, PL). Total creatine content was significantly elevated after the Cr-mH supplementation period as compared to placebo in each of the studies. Neither Cr-mH supplementation, nor exercise training resulted in measurable alterations in CRT protein content and acute Cr-mH loading did not alter CRT mRNA. There were no gender differences in CRT mRNA or total creatine content in the young subjects and no gender differences in total creatine content or CRT protein content in the elderly subjects. Weight training in young men did not increase CS protein content, however, in the elderly there was a significant increase in CS protein content after exercise training (p < 0.05). These results demonstrated that Cr-mH supplementation during weight training resulted in increases in skeletal muscle total creatine without reductions in CRT protein and acute Cr-mH loading did not decrease CRT mRNA content.
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PMID:Acute and moderate-term creatine monohydrate supplementation does not affect creatine transporter mRNA or protein content in either young or elderly humans. 1270 26