Slow contractions characterize failing rat hearts.

The reduced power of the failing heart can be ascribed to a combination of reduced force and slower contraction. We hypothesized that these two properties are due to different cellular mechanisms. We measured contraction parameters both in vivo and in isolated left ventricular (LV) cardiomyocytes from a rat model of post infarction congestive heart failure (CHF). ECG was measured simultaneously with echocardiography and LV pressure, respectively. Shortening and shortening velocity (SV) in isolated cardiomyocytes were measured during different stimulation protocols. LV end diastolic pressure (LVEDP) was 24.6 +/- 0.7 mmHg in CHF. LV systolic pressure was decreased by 20%, maximum rate of pressure development in the LV (+dP/dtmax) by 36% and time in systole increased by 20% in CHF compared to sham. Electrical remodelling occurred in CHF cells, which were depolarized and had prolonged action potentials (AP) compared to sham cells. Fractional shortening (FS) was increased in CHF compared to sham independent of stimulation protocol. Larger FS was accompanied by increased sarcoplasmic reticulum (SR) Ca2+ load and depended on the electrical remodelling. Time to peak contraction (TTP) was increased in CHF compared to sham cells, but in contrast to FS, TTP was only slightly affected when the cells were stimulated with sham APs and sham diastolic membrane potential (DMP). Contraction duration (corresponding to systolic duration) was 25% longer in CHF than in sham independent on stimulation protocol. We conclude that electrical remodelling affecting DMP and AP duration (APD) significantly affects the size of contraction, whereas the mechanism for slowing of contraction in CHF is different.

Effects of congestive heart failure on Ca2+ handling in skeletal muscle during fatigue.

Skeletal muscle weakness and decreased exercise capacity are major symptoms reported by patients with congestive heart failure (CHF). Intriguingly, these skeletal muscle symptoms do not correlate with the decreased heart function. This suggests that CHF leads to maladaptive changes in skeletal muscles, and as reported most markedly in slow-twitch muscles. We used rats at 6 weeks after infarction to measure expression of key proteins involved in SR Ca(2+) release and uptake in slow-twitch soleus muscles. We also measured force and myoplasmic free [Ca(2+)] ([Ca(2+)](i)) in intact single fibers of soleus muscles. CHF rats showed clear signs of severe cardiac dysfunction with marked increases in heart weight and left ventricular end-diastolic pressure compared with sham operated rats (Sham). There were small, but significant, changes in the content of proteins involved in cellular Ca(2+) handling in CHF muscles: slight increases in SR Ca(2+) release channels (ie, the ryanodine receptors) and in SR Ca(2+)-ATPase. Tetanic force and [Ca(2+)](i) were not significantly different between CHF and Sham soleus fibers under resting conditions. However, during the stimulation period there was a decrease in tetanic force without changes in [Ca(2+)](i) in CHF fibers that was not observed in Sham fibers. The fatigue-induced changes recovered rapidly. We conclude that CHF soleus fibers fatigue more rapidly than Sham fibers because of a reversible fatigue-induced decrease in myofibrillar function.

Cardiopulmonary alterations in mRNA expression for interleukin-1beta, the interleukin-6 superfamily and CXC-chemokines during development of postischaemic heart failure in the rat.

Cytokines and chemokines are believed to play a pathogenic role in heart failure (HF). Although some cytokines and chemokines have been examined in HF, information about others is still lacking. We aimed to examine the expression of cytokines belonging to the interleukin (IL)-6 superfamily [IL-6 and ciliary neurotrophic factor (CNTF)], as well as IL-1beta and the CXC-chemokines monocyte chemoattractant protein-1 (MCP-1) and IL-8. We examined their expression in the heart, lung and spleen during development of postischaemic HF 1 and 6 weeks following left coronary artery ligation. Rats, which after myocardial infarction had a left ventricular end-diastolic pressure above 15 mmHg, were considered to be in HF. Sham-operated rats served as controls. A substantial upregulation of cardiac IL-1beta was measured in HF at 1 week, whereas a downregulation was measured in the lungs. At 6 weeks no altered regulation was seen. CNTF was only upregulated in the viable left ventricle at 6 weeks and IL-6 was upregulated in the infarcted region at 1 week. Cardiac MCP-1 was upregulated in the viable and the infarcted region of the failing left ventricle at 1 week, with the highest expression in the latter. In the lung, another pattern of regulation was seen with a significant increase in pulmonary MCP-1 at 6 weeks. IL-8 was only detected in the infarcted region at 1 week. In the spleen, no regulation of cytokines was found. In conclusion, we report an organ-specific regulation of cytokines and chemokines in postischaemic HF. Our novel findings of increased cardiac CNTF and cardiopulmonary MCP-1 mRNA indicate a role for these factors in the pathogenesis of HF.

Increased cardiac IL-18 mRNA, pro-IL-18 and plasma IL-18 after myocardial infarction in the mouse; a potential role in cardiac dysfunction.

OBJECTIVE: Interleukin (IL)-18 has been reported to be an important predictor for mortality in ischemic heart disease. IL-18 has proinflammatory properties, induces cell death and stimulates nitric oxide production. We hypothesized that following myocardial infarction (MI) an increased myocardial IL-18 production occurs, which may be involved in the pathogenesis of post-ischemic heart failure. METHODS AND RESULTS: Seven days after induction of MI in the mouse, myocardial hypertrophy and pulmonary edema were observed. RNase protection assay of tissue from the non-infarcted left ventricular myocardium revealed an increase in IL-18 (2.0-fold; P<0.001) and IL-1 beta (1.6-fold; P<0.001) mRNA after MI. Enhanced abundance of pro-IL-18 (1.4-fold; P<0.05), IL-18 receptor (3.5-fold; P<0.05) and IL-18 binding proteins (1.6-fold; P<0.05) was also demonstrated, whereas cardiac IL-18 protein decreased by 25% (P<0.05) following MI. However, the concentration of circulating IL-18 was significantly elevated (MI; 90.4+/-11.7 pg/ml, sham; 47.2+/-4.2 pg/ml; P<0.001). After MI, enhanced cardiac activity of the pro-IL-18 processing enzyme, caspase-1, was measured. Additionally, a 3.4-fold increase (P<0.001) in the activity of the IL-18 degrading enzyme, caspase-3, was found in cardiac tissue, which may explain the observed reduction of cardiac IL-18 protein abundance. Finally, IL-18 reduced shortening of electrically stimulated adult cardiomyocytes and left ventricular contractility in vivo. CONCLUSIONS: After MI in the mouse, increased production of cardiac IL-18 mRNA and pro-IL-18, as well as circulating IL-18 occurs. Since IL-18 also reduced myocardial contractility, we suggest that IL-18 may be involved in the pathogenesis of contractile dysfunction following MI.