Mechanisms of creatine depletion in chronically failing rat heart.

The failing myocardium is characterised by energetic imbalance, reflected by reduced phosphocreatine and creatine content. These changes may contribute to cardiac dysfunction, yet mechanisms of creatine and phosphocreatine depletion are poorly understood. Creatine is taken up by the heart via the creatine transporter. We investigated the mechanisms leading to myocardial creatine depletion in heart failure. Therefore rats were subjected to chronic left coronary artery ligation (MI; n = 36) or to sham operation (sham; n = 25). After 8 weeks, hearts were perfused with 14C-creatine buffer to determine creatine uptake rates via the creatine transporter. Total creatine content was determined by HPLC. Creatine transport in sham hearts followed Michaelis-Menten kinetics with a V(max) of 5.9 +/- 0.5 nmol/min per gww. Heart failure led to a significant 30% decrease in intracellular creatine content and to a significant 26% reduction in creatine uptake (V(max) in MI 4.3 +/- 0.4 nmol/min per gww; P < 0.001 vs. sham). We conclude that depletion of creatine/phosphocreatine content in the failing heart is due to reduced sarcolemmal creatine uptake. The creatine transporter may be a potential therapeutic target to prevent energetic imbalance in heart failure.

The PPARgamma-activator rosiglitazone does not alter remodeling but increases mortality in rats post-myocardial infarction.

OBJECTIVE: Peroxisome proliferator-activated receptor gamma (PPARgamma) activators may be beneficial in heart failure due to their metabolic and antihypertrophic effects, but these agents can cause oedema. We hypothesized that, on balance, the PPARgamma activator rosiglitazone would be beneficial in heart failure post-myocardial infarction. METHODS AND RESULTS: Rosiglitazone (3 mg/kg/day p.o.) given to male Wistar rats for 14 days, caused a 31% increase in left ventricular (LV) dP/dt(max) (P<0.05 vs. placebo). A separate group of rats was subjected to sham (SH) or coronary artery ligation and randomised to: untreated (UT); rosiglitazone 3 mg/kg/day (R); captopril, 2 g/l in drinking water (C); captopril+rosiglitazone (C+R). Mean LV infarct sizes were similar for all groups at 40+/-2%. After 8 weeks, echocardiographic ejection fractions were 82+/-3, 40+/-3, 50+/-2*, 49+/-2, 50+/-3% for SH, UT, R, C and C+R groups, respectively (*P<0.05 vs. UT). Captopril prevented LV dilatation, but rosiglitazone did not. In vivo hemodynamics showed that only UT had significantly elevated LV end-diastolic pressures and reduced +dP/dt(max), with R partially, and C and C+R almost completely preventing the increase in LVEDP. Captopril, but not rosiglitazone, significantly reduced LV hypertrophy [LV/bw; 1.97+/-0.09 (SH), 2.15+/-0.04 (UT), 2.10+/-0.05 (R), 1.81+/-0.04* (C), 1.88+/-0.07 (C+R); *(P<0.05 vs. UT)]. Rosiglitazone increased 8-week mortality, which was 26% for R and 19% for C+R compared with 0% for UT and C (P=0.03 vs. UT). CONCLUSIONS: Rosiglitazone did not modulate LV remodeling, but was associated with increased mortality post-myocardial infarction (MI) in rats. The mechanisms require further study, but these results caution against use of PPARgamma activators in post-MI heart failure in non-diabetics.

Creatine transporter activity and content in the rat heart supplemented by and depleted of creatine.

The intracellular creatine concentration is an important bioenergetic parameter in cardiac muscle. Although creatine uptake is known to be via a NaCl-dependent creatine transporter (CrT), its localization and regulation are poorly understood. We investigated CrT kinetics in isolated perfused hearts and, by using cardiomyocytes, measured CrT content at the plasma membrane or in total lysates. Rats were fed control diet or diet supplemented with creatine or the creatine analog beta-guanidinopropionic acid (beta-GPA). Creatine transport in control hearts followed saturation kinetics with a K(m) of 70 +/- 13 mM and a V(max) of 3.7 +/- 0.07 nmol x min(-1) x g wet wt(-1). Creatine supplementation significantly decreased the V(max) of the CrT (2.7 +/- 0.17 nmol x min(-1) x g wet wt(-1)). This was matched by an approximately 35% decrease in the plasma membrane CrT; the total CrT pool was unchanged. Rats fed beta-GPA exhibited a >80% decrease in tissue creatine and increase in beta-GPA(total). The V(max) of the CrT was increased (6.0 +/- 0.25 nmol x min(-1) x g wet wt(-1)) and the K(m) decreased (39.8 +/- 3.0 mM). The plasma membrane CrT increased about fivefold, whereas the total CrT pool remained unchanged. We conclude that, in heart, creatine transport is determined by the content of a plasma membrane isoform of the CrT but not by the total cellular CrT pool.