Cardiac UCP2 expression and myocardial oxidative metabolism during acute septic shock in the rat.

Septic shock decreases cardiac hydraulic work relative to the rate of myocardial oxygen consumption, causing decreased mechanical efficiency (hydraulic work/myocardial oxygen consumption). This study tested whether the mitochondrial uncoupling protein UCP2 was responsible for decreased cardiac mechanical efficiency after polymicrobial septic shock. Sepsis was initiated in ketamine/xylazine-anesthetized rats by cecal ligation and puncture (CLP). Steady-state mRNA content was quantified by Northern blot analysis, and protein content was estimated by western blot. Additional hearts were removed after 12 h and perfused in working mode to measure work (mmHg x mUmin/100g dry wt) and efficiency (CE= work/ oxygen consumption, %). The 72-h mortality rate was 80%, and deaths occurred between 12-32 h. Cardiac work (152 ± 15, shock vs. 235 ± 16, control; P < 0.05) and cardiac efficiency (4.0 ± 0.4 vs. 5.6 ± 0.3; P< 0.05) were significantly decreased when hearts were isolated 12 h after CLP. Myocardial UCP2 mRNA expression was increased by 52% (12 h) compared with control hearts; however, there was no detectable UCP2 protein in mitochondria isolated from either control or septic hearts. Conclusions: Although polymicrobial sepsis decreased cardiac mechanical efficiency and increased UCP-2 expression coincident with premortal hypothermia, we did not detect any evidence of UCP-2 protein in septic heart muscle. These data argue against the hypothesis that UCP-2 causes decreased cardiac mechanical efficiency in septic shock.