High intracellular Na+ preserves myocardial function at low heart rates in isolated myocardium from failing hearts.

We investigated the hypothesis that increased intracellular [Na+]i in heart failure contributes to preservation of SR Ca2+ load which may become particularly evident at slow heart rates. [Na+]i in SBFI-loaded myocytes from rabbits with pacing-induced heart failure (PHF) was significantly higher at each frequency as compared to Sham-operated animals. Furthermore, PHF rabbits demonstrated reduced SR Ca2+-ATPase protein levels (-37%, p < 0.04) but unchanged Na+/Ca2+ exchanger protein levels. At 0.25 Hz, isometric force was similar in cardiac trabeculae from PHF rabbits as compared to control (PHF, 3.6+/-1.3; Sham, 4.4+/-0.6 mN/mm2). Rapid cooling contractures (RCCs) were unchanged indicating preserved SR Ca2+ load at this frequency. In Sham, isometric twitch force increased with rising frequencies to 29.0+/-2.8 mN/mm2 at 3.0 Hz (p < 0.05) as compared to 0.25 Hz. RCCs showed a parallel increase by 186+/-47% (p < 0.01). In PHF, frequency-dependent increase in force (15.8+/-4.7 mN/mm2 at 3.0 Hz) and RCCs (increase by 70+/-40%) were significantly blunted. Thus, in PHF in rabbits SR Ca2+ load is preserved at low frequencies despite decreased SR Ca2+-ATPase expression. This may result from [Na+]i-dependent changes in Na+/Ca2+ exchanger activity.

Identification of macrophage arginase I as a new candidate gene of atherosclerosis resistance.

OBJECTIVE: Our laboratory has previously created 2 strains of rabbits with genetically determined high-atherosclerotic response (HAR) and low-atherosclerotic response (LAR). The aim of the present study was to identify new genes of atherosclerosis susceptibility in macrophages from the 2 strains. METHODS AND RESULTS: Suppression subtractive hybridization was used to screen for genes with higher expression in macrophages from LAR rabbits. We identified a cDNA fragment with high homology to human arginase I (AI; 91%) and subsequently cloned the full-length cDNA of the rabbit homologue. Quantitative RT-PCR revealed a significantly higher macrophage AI mRNA expression in LAR rabbits than in HAR rabbits (77428+/-10941 versus 34344+/-4538; P=0.002; copies/10(6) copies beta-actin), which also correlated with a significantly higher arginase enzyme activity. Northern blot analysis led to the identification of a size polymorphism of AI mRNA. This was because of a 413 bp C-repeat insertion in the 3' untranslated region. The shorter transcript variant was predominantly expressed in LAR rabbits and associated with significantly higher AI mRNA expression levels. Transfection experiments indicated decreased mRNA stability of the long AI variant. CONCLUSIONS: High expression of arginase I in macrophages may contribute to atherosclerosis resistance of LAR rabbits, possibly by conferring antiinflammatory effects in the vessel wall.