High glucose protects embryonic cardiac cells against simulated ischemia.

In the present study we investigated whether acute glucose administration could be protective against hypoxic stress. H9c2 cells were exposed to either 4.5 mM or 22 mM of glucose for 15,min and then were submitted to simulated ischemia. Cell death was microscopically assessed by combined staining with propidium iodide (PI) and Hoeschst 33358. Intracellular content of glucose was measured by enzymatic analysis. Clucose content of H9c2 cells was 48.24+/- 7.94 micromol/L in the 22 mM vs 23.86+/- 4.8 micromol/L in the 4.5 mM group (p < 0.05). PKCepsilon expression was increased 1.6 fold in the membrane fraction after pretreatment with high glucose (p < 0.05), while was decreased 1.6 fold in the cytosol (p < 0.05). In addition, no difference to PKCdelta translocation was observed after pretreatment with low glucose. After hypoxia, in the 22 mM group, cell death was found to be 17.36+/- 2.66% vs 38.2+/- 5.4% in the 4.5 mM group (p < 0.05). In the presence of iodoacetic acid, a glycolytic inhibitor, cell death was not different between the two groups (23.54+/- 3.2% in 22 mM vs 22.06+/- 5.3% in 4.5 mM). Addition of chelerythrine did not change the protective effect of high glucose (13.4+/- 1.7% cell death in 22 mM vs 27.5+/- 5.5% in 4.5 mM, p < 0.05). In conclusion, short pretreatment with high glucose protects H9c2 cells against hypoxia. Although this protective effect is associated with translocation of PKCepsilon and increased glucose uptake, it was abrogated only by inhibition of glycolysis.

Thyroxine pretreatment increases basal myocardial heat-shock protein 27 expression and accelerates translocation and phosphorylation of this protein upon ischaemia.

Thyroxine pretreatment increases the tolerance of the heart to ischaemia, and heat-shock protein 27 (HSP27) is considered to play an important role in cardioprotection. The present study investigated whether long-term thyroxine administration can induce changes in the expression, translocation and phosphorylation of HSP27 at baseline and upon ischaemic stress. L-Thyroxine (T(4)) was administered to Wistar rats (25 microg/100 g/day s.c.) for 2 weeks, while normal animals served as controls. Hearts from normal and thyroxine-treated rats were perfused in Langendorff mode and subjected to 10 or 20 min of zero-flow global ischaemia only or to 20 min of ischaemia followed by 45 min of reperfusion. Total and phospho-HSP27 expression were assessed at different times in the Triton-soluble (cytosol-membrane), S fraction, and the Triton-insoluble (cytoskeleton-nucleus) fraction, P fraction. Postischaemic recovery of left ventricular developed pressure at 45 min of reperfusion was expressed as % of the initial value. In hearts from thyroxine-treated animals, the levels of basal total HSP27 and phospho-HSP27 in the P fraction were significantly increased as compared to normal. In response to ischaemia, in hearts from thyroxine-treated rats, the levels of total HSP27 and phospho-HSP27 were found to be significantly increased in the P fraction at 10 and 20 min of ischaemia as compared to preischaemic values, whereas in normal hearts, the levels of total HSP27 and phospho-HSP27 were significantly increased at 20 min only. Postischaemic functional recovery was significantly greater in thyroxine-treated than in untreated hearts. In summary, long-term thyroxine pretreatment results in an increased basal expression and phosphorylation of HSP27 and in an earlier and sustained redistribution of HSP27 from the S to the P fraction in response to ischaemia. This effect might be of important therapeutic relevance.

Loss of cardioprotection induced by ischemic preconditioning after an initial ischemic period in isolated rat hearts.

BACKGROUND: The beneficial effect of ischemic preconditioning (PC) has been extensively studied in normal hearts but its effects on diseased hearts remain largely unknown. The effect of PC in the already ischemic myocardium has not been previously studied, although ischemia in varying intervals, which is difficult to assess, is often encountered in clinical practice. OBJECTIVE: To investigate whether the cardioprotective effect of PC is preserved when it is applied after a period of ischemia of varying duration. METHODS: Male Wistar rats were used for this study. Isolated normal rat hearts were perfused in Langendorff mode. Before 20 min of zero flow global ischemia followed by 45 min of reperfusion, hearts were subjected to an initial 20-min period of ischemia followed by 10 min of reperfusion (group A1); an initial 20-min period of ischemia followed by 10 min of reperfusion and two-cycle PC (3 min of ischemia, 5 min of reperfusion followed by 5 min of ischemia and 5 min of reperfusion) (group A2); and two-cycle PC followed by the initial 20-min period of ischemia and 10 min of reperfusion (group A3). Groups B and C were subjected to an initial ischemia of 15 min and 10 min, respectively, and subgroups 1, 2 and 3 were treated as above. Left ventricular end-diastolic pressure was measured at 45 min of reperfusion (LVEDP45 in mmHg). Postischemic recovery of left ventricular developed pressure was expressed as a percentage of the initial value (LVDP%). RESULTS: LVDP% and LVEDP45 were similar between groups A1 and A2, while when ischemic preconditioning preceded the two periods of ischemia (group A3), it resulted in significantly higher LVDP% and significantly lower LVEDP45 compared with groups A1 and A2. Left ventricular functional recovery was not increased in group B2 compared with group B1. LVDP% and LVEDP45 were similar among groups C1, C2 and C3. CONCLUSION: Ischemic preconditioning does not improve functional recovery in isolated rat hearts that have been initially subjected to 20 min or 15 min of zero-flow global ischemia, while an initial 10-min ischemic period seems to precondition the heart.