Increasing doxorubicin activity against breast cancer cells using PPARγ-ligands and by exploiting circadian rhythms.

BACKGROUND AND PURPOSE: Doxorubicin is effective against breast cancer, but its major side effect is cardiotoxicity. The aim of this study was to determine whether the efficacy of doxorubicin on cancer cells could be increased in combination with PPARγ agonists or chrono-optimization by exploiting the diurnal cycle. EXPERIMENTAL APPROACH: We determined cell toxicity using MCF-7 cancer cells, neonatal rat cardiac myocytes and fibroblasts in this study. KEY RESULTS: Doxorubicin damages the contractile filaments of cardiac myocytes and affects cardiac fibroblasts by significantly inhibiting collagen production and proliferation at the level of the cell cycle. Cyclin D1 protein levels decreased significantly following doxorubicin treatment indicative of a G1/S arrest. PPARγ agonists with doxorubicin increased the toxicity to MCF-7 cancer cells without affecting cardiac cells. Rosiglitazone and ciglitazone both enhanced anti-cancer activity when combined with doxorubicin (e.g. 50% cell death for doxorubicin at 0.1 µM compared to 80% cell death when combined with rosiglitazone). Thus, the therapeutic dose of doxorubicin could be reduced by 20-fold through combination with the PPARγ agonists, thereby reducing adverse effects on the heart. The presence of melatonin also significantly increased doxorubicin toxicity, in cardiac fibroblasts (1 µM melatonin) but not in MCF-7 cells. CONCLUSIONS AND IMPLICATIONS: Our data show, for the first time, that circadian rhythms play an important role in doxorubicin toxicity in the myocardium; doxorubicin should be administered mid-morning, when circulating levels of melatonin are low, and in combination with rosiglitazone to increase therapeutic efficacy in cancer cells while reducing the toxic effects on the heart.

Low-dose ramipril treatment improves relaxation and calcium cycling after established cardiac hypertrophy.

Rapid cooling contractures were used in this study to test whether low-dose ramipril improves sarcoplasmic reticulum (SR) Ca(2+) uptake and Na(+)/Ca(2+) exchanger function in isolated hypertrophied rat myocytes. Compensated cardiac hypertrophy was induced by abdominal aortic constriction for 5 wk followed by administration of ramipril (50 microg x kg(-1) x day(-1)) or vehicle for 4 wk. Myocyte cell length and cell width were significantly (P < 0.05) increased in both hypertrophied groups (+/-ramipril). Myocytes were loaded with indo 1, and relaxation was investigated after rapid cooling. Hypertrophied myocyte relaxation in Na(+)-free/Ca(2+)-free solution was 63% slower (P < 0.01) and the fall in intracellular Ca(2+) was 60% slower (P < 0.05) than the relaxation of control cells. After ramipril treatment both relaxation and the decline in intracellular Ca(2+) returned to control rates through improved SR Ca(2+)-ATPase function. Relaxation in caffeine showed no change after hypertrophy; however, after ramipril treatment the time to 50% relaxation in caffeine decreased by 30% (P < 0.05). The improvement in Ca(2+) extrusion across the sarcolemmal membrane occurred independently of changes in Na(+)/Ca(2+) exchanger mRNA and protein abundance. These data demonstrate that ramipril improves both SR-dependent and non-SR-dependent calcium cycling after established cardiac hypertrophy. However, the improvements in function are independent of transcriptional activation and likely to involve altered intracellular ion concentrations.

Sarco(endo)plasmic reticulum Ca(2+)-ATPase (SERCA2) gene products are regulated post-transcriptionally during rat cardiac development.

OBJECTIVE: The Sarco(endo)plasmic reticulum Ca(2+)-ATPase (SERCA2) plays a major role in the contraction-relaxation cycle and is responsible for transporting calcium into the lumen of the sarcoplasmic reticulum. This study was performed to determine if the increase in SERCA2 messenger RNA (mRNA) abundance during the perinatal period is regulated transcriptionally. METHODS: Transcriptional activity was determined by nuclear run-on assays and mRNA and protein abundances were determined during late fetal and early neonatal cardiac development in rat. RESULTS: From nuclear run-on assays, SERCA2 gene transcription at 17/18 embryonic days (139 +/- 41 parts per million (ppm), n = 7) did not differ from that at 20 neonatal days (139 +/- 37 ppm, n = 6) after birth. No increase in transcriptional activity could be demonstrated during the time frame examined. In contrast, both alpha and beta myosin heavy chains showed significant changes in measured transcriptional activity. SERCA2 mRNA normalized to 18S RNA levels are very low in the fetus (9.8 +/- 1.9 to 13.4 +/- 4.9 arbitrary units (A.U.) from 17/18 to 19/20 embryonic days) and significantly increase from birth (15 +/- 3.8 A.U.) to reach a maximum at 20 days of age (29.1 +/- 9.5 to 48.3 +/- 7.0 in 15 to 20 neonatal days rats respectively). Similarly, SR Ca(2+)-ATPase protein levels are less abundant in the fetus (0.82 +/- 0.08 to 1.13 +/- 0.13 A.U./microgram total protein) and reach a maximum at 15-20 neonatal days (3.08 +/- 0.58 to 2.98 +/- 0.17). Ca2+ uptake in the fetal heart is about one sixth the level seen in the adult, reaches the highest observed value at 5 days after birth (6.05 +/- 0.77 pmole Ca2+ per microgram/min) and remains relatively constant over the next 15 days. The activity increases even though phospholamban protein increases in abundance. CONCLUSIONS: Since the transcriptional activity of this gene is unchanged whereas the mRNA, protein abundance and activity increase, we conclude that the abundance of SERCA2 gene products is regulated primarily through post-transcriptional mechanisms during the perinatal period.

Sub-antihypertensive doses of ramipril normalize sarcoplasmic reticulum calcium ATPase expression and function following cardiac hypertrophy in rats.

We examined the hypothesis that the angiotensin converting enzyme inhibitor ramipril at sub-antihypertensive concentrations could improve sarcoplasmic reticulum (SR) CaATPase expression and function in compensated hypertrophied rat hearts. Five weeks after abdominal aortic constriction, rats received a daily dose (50 micrograms/kg/day) of ramipril or vehicle for 4 weeks. Cardiac angiotensin-converting enzyme (ACE) activity increased with cardiac hypertrophy (CH) but returned to normal following ramipril treatment. SR CaATPase protein levels and activity decreased with CH (P < 0.05) and were normalized following ramipril treatment (P < 0.05 for protein and activity). No change in phospholamban (PLB) protein levels could be demonstrated between any of the groups. In contrast, ramipril treatment specifically increased control SR CaATPase and PLB mRNA levels by > 60% (P < 0.01) and > 30%, respectively. In the hypertrophied group, SR CaATPase increased by 35% (P < 0.05 n = 6) after ramipril treatment. Calsequestrin mRNA levels were unaffected by ramipril administration. In conclusion, ramipril normalizes SR CaATPase protein expression and function in pressure-overloaded and compensated CH. The effects of ramipril are however multifaceted, affecting RNA and protein expression differentially.

Kinetics of induction and protective effect of heat-shock proteins after cardioplegic arrest.

BACKGROUND: Heat-shock proteins are known to enhance cardiac resistance to ischemia. METHODS: To evaluate the kinetics of heat-shock protein 70 in relation to its effect on postischemic recovery of cardiac mechanical (cardiac output) and endothelial function (as percentage increase of coronary flow in response to 5-hydroxytryptamine), isolated rat hearts were subjected to prolonged hypothermic cardioplegic arrest at different intervals ranging from 12 to 96 hours after heat stress (n = 6 in each interval). RESULTS: Immunoblotting showed the maximal level of heat-shock protein 70, 0.65 +/- 0.10 (arbitrary units +/- standard error of the mean), at 24 hours after heat shock and similar values at 26 and 30 hours (p = not significant). Postischemic recovery of cardiac output and endothelial function (percentage of preischemic value +/- standard error of the mean) observed at 24 hours was 74.0 +/- 2.4 and 58.3 +/- 7.2, respectively. Similar values were observed at 26 and 30 hours (p = not significant). CONCLUSIONS: In a protocol mimicking conditions for cardiac transplantation, postischemic recovery of cardiac output and endothelial function was improved when the interval between heat stress and ischemia ranged from 24 to 30 hours. This correlated with an apparently critical amount of heat-shock protein 70.

Induction of heat-shock proteins enhances myocardial and endothelial functional recovery after prolonged cardioplegic arrest.

The aim of this study was to investigate the role of heat-shock proteins after heat-shock stress on the post-ischemic recovery of cardiac mechanical and endothelial function following a prolonged cardiac arrest. Isolated working rat hearts were subjected to a cardioplegic arrest for 4 hours at 4 degrees C. Three groups (n = 8 in each) were studied: (1) control, (2) sham-treated, and (3) heat-shocked rats. Postischemic recovery of cardiac output and endothelial function (as percent of preischemic control values) was 57.8% +/- 2.8% and 20.8% +/- 3.9% in group 1, 50.9% +/- 4.0% and 26.3% +/- 5.9% in group 2, and 74.0% +/- 2.4% and 51.2% +/- 8.0% in group 3, respectively. Both postischemic myocardial and endothelial function were improved by heat stress.