Ribose supplementation alone or with elevated creatine does not preserve high energy nucleotides or cardiac function in the failing mouse heart

Background: Reduced levels of creatine and total adenine nucleotides (sum of ATP, ADP and AMP) are hallmarks of chronic heart failure and restoring these pools is predicted to be beneficial by maintaining the diseased heart in a more favourable energy state. Ribose supplementation is thought to support both salvage and re-synthesis of adenine nucleotides by bypassing the rate-limiting step. We therefore tested whether ribose would be beneficial in chronic heart failure in control mice and in mice with elevated myocardial creatine due to overexpression of the creatine transporter (CrT-OE). Methods and Results: Four groups were studied: sham; myocardial infarction (MI); MI+ribose; MI+CrT-OE+ribose. In a pilot study, ribose given in drinking water was bioavailable, resulting in a two-fold increase in myocardial ribose-5-phosphate levels. However, 8 weeks post-surgery, total adenine nucleotide (TAN) pool was decreased to a similar amount (8–14%) in all infarcted groups irrespective of the treatment received. All infarcted groups also presented with a similar and substantial degree of left ventricular (LV) dysfunction (3-fold reduction in ejection fraction) and LV hypertrophy (32–47% increased mass). Ejection fraction closely correlated with infarct size independently of treatment (r2 = 0.63, p<0.0001), but did not correlate with myocardial creatine or TAN levels. Conclusion: Elevating myocardial ribose and creatine levels failed to maintain TAN pool or improve post-infarction LV remodeling and function. This suggests that ribose is not rate-limiting for purine nucleotide biosynthesis in the chronically failing mouse heart and that alternative strategies to preserve TAN pool should be investigated

Changes in creatine transporter function during cardiac maturation in the rat

<p>Abstract</p> <p>Background</p> <p>It is well established that the immature myocardium preferentially utilises non-oxidative energy-generating pathways. It exhibits low energy-transfer capacity via the creatine kinase (CK) shuttle, reflected in phosphocreatine (PCr), total creatine and CK levels that are much lower than those of adult myocardium. The mechanisms leading to gradually increasing energy transfer capacity during maturation are poorly understood. Creatine is not synthesised in the heart, but taken up exclusively by the action of the creatine transporter protein (CrT). To determine whether this transporter is ontogenically regulated, the present study serially examined CrT gene expression pattern, together with creatine uptake kinetics and resulting myocardial creatine levels, in rats over the first 80 days of age.</p> <p>Results</p> <p>Rats were studied during the late prenatal period (-2 days before birth) and 7, 13, 21, 33, 50 and 80 days after birth. Activity of cardiac citrate synthase, creatine kinase and its isoenzymes as well as lactate dehydrogenase (LDH) and its isoenzymes demonstrated the well-described shift from anaerobic towards aerobic metabolism. mRNA levels of CrT in the foetal rat hearts, as determined by real-time PCR, were about 30% of the mRNA levels in the adult rat heart and gradually increased during development. Creatine uptake in isolated perfused rat hearts increased significantly from 3.0 nmol/min/gww at 13 days old to 4.9 nmol/min/gww in 80 day old rats. Accordingly, total creatine content in hearts, measured by HPLC, increased steadily during maturation (30 nmol/mg protein (-2 days) vs 87 nmol/mg protein (80 days)), and correlated closely with CrT gene expression.</p> <p>Conclusions</p> <p>The maturation-dependant alterations of CK and LDH isoenzyme activities and of mitochondrial oxidative capacity were paralleled by a progressive increase of CrT expression, creatine uptake kinetics and creatine content in the heart.</p

Chronic creatine kinase deficiency eventually leads to congestive heart failure, but severity is dependent on genetic background, gender and age

The creatine kinase (CK) energy transport and buffering system supports cardiac function at times of high demand and is impaired in the failing heart. Mice deficient in muscle- and mitochondrial-CK (M/Mt-CK(−/−)) have previously been described, but exhibit an unexpectedly mild phenotype of compensated left ventricular (LV) hypertrophy. We hypothesised that heart failure would develop with age and performed echocardiography and LV haemodynamics at 1 year. Since all previous studies have utilised mice with a mixed genetic background, we backcrossed for >10 generations on to C57BL/6, and repeated the in vivo investigations. Male M/Mt-CK(−/−) mice on the mixed genetic background developed congestive heart failure as evidenced by significantly elevated end-diastolic pressure, impaired contractility, LV dilatation, hypertrophy and pulmonary congestion. Female mice were less severely affected, only showing trends for these parameters. After backcrossing, M/Mt-CK(−/−) mice had LV dysfunction consisting of impaired isovolumetric pressure changes and reduced contractile reserve, but did not develop congestive heart failure. Body weight was lower in knockout mice as a consequence of reduced total body fat. LV weight was not significantly elevated in relation to other internal organs and gene expression of LVH markers was normal, suggesting an absence of hypertrophy. In conclusion, the consequences of CK deficiency are highly dependent on genetic modifiers, gender and age. However, the observation that a primary defect in CK can, under the right conditions, result in heart failure suggests that impaired CK activity in the failing heart could contribute to disease progression. ELECTRONIC SUPPLEMENTARY MATERIAL: The online version of this article (doi:10.1007/s00395-012-0276-2) contains supplementary material, which is available to authorized users

On the pivotal role of PPARa in adaptation of the heart to hypoxia and why fat in the diet increases hypoxic injury

The role of peroxisome proliferator activated alpha (PPARα) -mediated metabolic remodeling in cardiac adaptation to hypoxia has yet to be defined. Here, mice were housed in hypoxia for 3 weeks before in vivo contractile function was measured using cine magnetic resonance (MR) imaging. In isolated, perfused hearts, energetics were measured using 31P MR spectroscopy and glycolysis and fatty acid oxidation were measured using 3H labelling. Compared with normoxic, chow-fed control mouse heart, hypoxia decreased PPARα expression, fatty acid oxidation and mitochondrial UCP3 levels, while increasing glycolysis, all of which served to maintain normal ATP concentrations and thereby ejection fractions. A high-fat diet increased cardiac PPARα expression, fatty acid oxidation and UCP3 levels, with decreased glycolysis. Hypoxia was unable to alter the high PPARα expression or reverse the metabolic changes caused by the high fat diet, with the result that ATP concentrations and contractile function decreased significantly. The adaptive metabolic changes caused by hypoxia in control mouse hearts were found to have already occurred in PPARα-/- mouse hearts, and sustained function in hypoxia despite an inability for further metabolic remodelling. We conclude that decreased cardiac PPARα expression is essential for adaptive metabolic remodelling in hypoxia, but is prevented by dietary fat

Modulation of myocardial creatine transporter levels and the effects of gene regulation and post-translational modification on its function

Heart failure (HF) is a common, disabling and deadly condition that causes high rates of morbidity and mortality worldwide. It is widely recognised that the failing heart is energy-starved, and that restoring energy homeostasis is a promising approach towards improving cardiac output. This thesis aims to address the role of energetics in the failing heart, by focussing on modulation of the creatine transporter (CrT). Creatine (Cr), together with the phosphocreatine shuttle, plays a vital role in maintaining energy supplies via ATP in times of high energy demand. Key to the regulation of intracellular [Cr] is the CrT, a Na+ and Cl- - dependent membrane transporter. Previous CrT genetic mouse models include a knockout model, found to still express cardiac CrT, and a cardiac-specific CrT overexpressing (OE) model with large variations in myocardial [Cr] between animals and Cr levels high enough to cause spontaneous hypertrophy. To overcome the shortfalls of this CrT-OE model, a novel in vivo model of temporal inducible expression of CrT is described, using a cardiac-specific tetracycline inducible (Tet-On) system. Ten transgenic lines (RCT) were created with a construct containing the CrT-HA (CrT cDNA with an haemagglutinin epitope tag), following successful doxycyline-inducibility in vitro. Eight lines showed germline transmission, with LV CrT OE achieved in an individual mouse that displayed double LV [Cr] compared to WT. Issues with the inducer line (rtTA) were ruled out by its use in the creation of a luciferase overexpressing mouse line; all mice tested demonstrated LV luciferase expression in response to doxycycline feeding. The failure to overexpress CrT could be attributed to position or copy number dependent suppression, or to position effect variegation in the case of the single OE mouse obtained. Subsequent work focussed on regulatory pathways in vitro in a cell line of mouse fibroblasts stably overexpressing CrT-HA. Post-translational modifications (PTMs) had been previously suggested to regulate CrT activity. Two N-linked glycosylation sites exist, in addition to the putative phosphorylation sites. Inhibition of glycosylation by tunicamycin led to decreased CrT activity, reflected by decreased Cr uptake capacity. Strategies to confirm the presence of phosphorylation were employed, including isolation of CrT-HA by immunoprecipitation and subsequent LC-MS / MS analysis to identify PTMs. Although the presence of CrT was confirmed in 5 different sized species- one previously unreported- inadequate sequence coverage prevented identification of any PTM sites. Tyrosine phosphorylation was not detected using a phosphospecific antibody on immunopurified CrT-HA. Candidate signalling pathways in vitro were then investigated to elucidate CrT regulation, namely the IGF 1R signalling pathway. This study included a cardiomyocyte-like mouse cell line (HL-1) in addition to 3T3-CrT-HA. Exposure of cells to extracellular insulin, growth hormone and IGF-1 led to increased Cr uptake of 125&amp;percnt; - 300&amp;percnt; of normal. Pharmacological inhibition of the downstream kinases PKA and PKC reduced the effect of insulin and GH, while PMA, sapintoxin (STX) and Gö 6976 induced CrT activity. The mammalian target of rapamycin (mTOR) is also a candidate regulator of CrT, as incubation with rapamycin decreased Cr uptake in 3T3-CrT-HA. Finally, a targeted approach on transcription factors in the 5'UTR region of mouse CrT identified HEY1 as a highly conserved site. In siRNA experiments, HEY1 was found to exert a mild effect on CrT activity, suggesting that regulation at the transcriptional level merits further investigation. Together, this work has provided novel insights into the modulation of CrT in vitro, identifying molecular and pharmacological targets in a known therapeutic signalling pathway. Further work could potentially develop these findings by identifying candidate compounds that would increase CrT activity, potentially in a tissue-specific manner.</p

Modulation of myocardial creatine transporter levels and the effects of gene regulation and post-translational modification

Heart failure (HP) is a common, disabling and deadly condition that causes high rates of morbidity and mortality worldwide. It is widely recognised that the failing heart is energy-starved, and that restoring energy homeostasis is a promising approach towards improving cardiac output. This thesis aims to address the role of energetics in the failing heart, by focussing on modulation of the creatine transporter (CrT). Creatine (Cr), together with the phosphocreatine shuttle, plays a vital role in maintaining energy supplies via ATP in times of high energy demand. Key to the regulation of intracellular [Cr] is the CrT, a Na+ and Cl - dependent membrane transporter. Previous CrT genetic mouse models include a knockout model, found to still express cardiac CrT, and a cardiac-specific CrT overexpressing (OE) model with large variations in myocardial [Cr] between animals and Cr levels high enough to cause spontaneous hypertrophy. To overcome the shortfalls of this CrT-OE model, a novel in vivo model of temporal inducible expression of CrT is described, using a cardiac-specific tetracycline inducible (Tet-On) system . ..,. .A' Ten transgenic lines (RCT) were created with a construct containing . zhe CrT-HA (CrT cDNA with an haemagglutinin epitope tag), following successful doxycyline-inducibility in vitro. Eight lines showed germline transmission, with LV CrT OE achieved in an individual mouse that displayed double LV [Cr] compared to WT. Issues with the inducer line (rtTA) were ruled out by its use in the creation of a luciferase overexpressing mouse line; all mice tested demonstrated LV luciferase expression in response to doxycycline feeding. The failure to overexpress CrT could be attributed to position or copy number dependent suppression, or to position effect variegation in the case of the single OE mouse obtained. Subsequent work focus sed on regulatory pathways in vitro in a cell line of mouse fibroblasts stably overexpressing CrT·HA. Post-translational modifications (PTMs) had been previously suggested to regulate CrT activity. Two N-linked glycosylation sites exist, in addition to the putative phosphorylation sites. Inhibition of glycosylation by tunicamycin led to decreased CrT activity, reflected by decreased Cr uptake capacity. Strategies to confirm the presence of phosphorylation were employed, including isolation of CrT -HA by immunoprecipitation and subsequent LC-MS / MS analysis to identify PTMs. Although the presence of CrT was confirmed in 5 different sized species- one previously unreported- inadequate sequence coverage prevented identification of any PTM sites. Tyrosine phosphorylation was not detected using a phosphospecific antibody on immunopurified CrT -HA. Candidate signalling pathways in vitro were then investigated to elucidate CrT regulation, namely the IGF-IR signalling pathway. This study included a cardiomyocyte-like mouse cell line (HL-l) in addition to 3T3-CrT -HA. Exposure of cells to extracellular insulin, growth hormone and IGF-1 led to increased Cr uptake of 125% - 300% of normal. Pharmacological inhibition of the downstream kinases PKA and PKC reduced the effect of insulin and GH, while PMA, sapintoxin (STX) and Go 6976 induced CrT activity. The mammalian target of rapamycin (mTOR) is also a candidate regulator of CrT, as incubation with rapamycin decreased Cr uptake in 3T3-CrT -HA. Finally, a targeted approach on transcription factors in the 5'UTR region of mouse CrT identified HEYl as a highly conserved site. In siRNA experiments, HEYl was found to exert a mild effect on CrT activity, suggesting that regulation at the transcriptional level merits further investigation. Together, this work has provided novel insights into the modulation of CrT in vitro, identifying molecular and pharmacological targets in a known therapeutic signalling pathway. Further work could potentially develop these findings by identifying candidate compounds that would increase CrT activity, potentially in a tissue-specific manner. 3EThOS - Electronic Theses Online ServiceGBUnited Kingdo

Modulation of myocardial creatine transporter levels and the effects of gene regulation and post-translational modification on its function

Heart failure (HF) is a common, disabling and deadly condition that causes high rates of morbidity and mortality worldwide. It is widely recognised that the failing heart is energy-starved, and that restoring energy homeostasis is a promising approach towards improving cardiac output. This thesis aims to address the role of energetics in the failing heart, by focussing on modulation of the creatine transporter (CrT). Creatine (Cr), together with the phosphocreatine shuttle, plays a vital role in maintaining energy supplies via ATP in times of high energy demand. Key to the regulation of intracellular [Cr] is the CrT, a Na+ and Cl- - dependent membrane transporter. Previous CrT genetic mouse models include a knockout model, found to still express cardiac CrT, and a cardiac-specific CrT overexpressing (OE) model with large variations in myocardial [Cr] between animals and Cr levels high enough to cause spontaneous hypertrophy. To overcome the shortfalls of this CrT-OE model, a novel in vivo model of temporal inducible expression of CrT is described, using a cardiac-specific tetracycline inducible (Tet-On) system. Ten transgenic lines (RCT) were created with a construct containing the CrT-HA (CrT cDNA with an haemagglutinin epitope tag), following successful doxycyline-inducibility in vitro. Eight lines showed germline transmission, with LV CrT OE achieved in an individual mouse that displayed double LV [Cr] compared to WT. Issues with the inducer line (rtTA) were ruled out by its use in the creation of a luciferase overexpressing mouse line; all mice tested demonstrated LV luciferase expression in response to doxycycline feeding. The failure to overexpress CrT could be attributed to position or copy number dependent suppression, or to position effect variegation in the case of the single OE mouse obtained. Subsequent work focussed on regulatory pathways in vitro in a cell line of mouse fibroblasts stably overexpressing CrT-HA. Post-translational modifications (PTMs) had been previously suggested to regulate CrT activity. Two N-linked glycosylation sites exist, in addition to the putative phosphorylation sites. Inhibition of glycosylation by tunicamycin led to decreased CrT activity, reflected by decreased Cr uptake capacity. Strategies to confirm the presence of phosphorylation were employed, including isolation of CrT-HA by immunoprecipitation and subsequent LC-MS / MS analysis to identify PTMs. Although the presence of CrT was confirmed in 5 different sized species- one previously unreported- inadequate sequence coverage prevented identification of any PTM sites. Tyrosine phosphorylation was not detected using a phosphospecific antibody on immunopurified CrT-HA. Candidate signalling pathways in vitro were then investigated to elucidate CrT regulation, namely the IGF 1R signalling pathway. This study included a cardiomyocyte-like mouse cell line (HL-1) in addition to 3T3-CrT-HA. Exposure of cells to extracellular insulin, growth hormone and IGF-1 led to increased Cr uptake of 125&percnt; - 300&percnt; of normal. Pharmacological inhibition of the downstream kinases PKA and PKC reduced the effect of insulin and GH, while PMA, sapintoxin (STX) and G&ouml; 6976 induced CrT activity. The mammalian target of rapamycin (mTOR) is also a candidate regulator of CrT, as incubation with rapamycin decreased Cr uptake in 3T3-CrT-HA. Finally, a targeted approach on transcription factors in the 5'UTR region of mouse CrT identified HEY1 as a highly conserved site. In siRNA experiments, HEY1 was found to exert a mild effect on CrT activity, suggesting that regulation at the transcriptional level merits further investigation. Together, this work has provided novel insights into the modulation of CrT in vitro, identifying molecular and pharmacological targets in a known therapeutic signalling pathway. Further work could potentially develop these findings by identifying candidate compounds that would increase CrT activity, potentially in a tissue-specific manner.</p

Oral ribose treatment increases ribose-5-phosphate levels in the heart.

<p>Myocardial ribose-5-phosphate levels following administration of ribose (10% w/v) in drinking water for seven weeks. Control n = 5, ribose n = 4, mean ± SD, ** denotes p<0.01.</p

Morphometry and myocardial biochemistry 8 weeks after myocardial infarction.

<p>All values are mean ± SD. Comparisons were made by one-way ANOVA with Bonferroni’s post-hoc test.</p>*<p>denotes p<0.05,</p>**<p>p<0.01,</p>***<p>p<0.001 vs group S and ^#p<0.05,</p>###<p>p<0.001 vs group MI.</p

Left ventricular morphology and function derived from MRI 8 weeks post myocardial infarction.

<p>Group S are untreated wild-type sham-operated mice; Group MI are untreated wild-type infarcted mice; Group MI+R are wild-type infarcted mice treated with ribose; Group MI+C+R are infarcted creatine transporter overexpressing mice treated with ribose. Infarcted groups were matched for infarct size (A). Left ventricular remodelling and function was measured by cine-MRI (B–F). Data are reported as mean ± SD. *** denotes p<0.001 (1-way ANOVA with Bonferroni’s correction).</p