Long-chain free fatty acids inhibit ischaemic preconditioning of the isolated rat heart.

We recently reported that non-preconditioned hearts from diet-induced obese rats showed, compared to controls, a significant reduction in infarct size after ischaemia/reperfusion, whilst ischaemic preconditioning was without effect. In view of the high circulating FFA concentration in diet rats, the aims of the present study were to: (i) compare the effect of palmitate on the preconditioning potential of hearts from age-matched controls and diet rats (ii) elucidate the effects of substrate manipulation on ischaemic preconditioning. Substrate manipulation was done with dichloroacetate (DCA), which enhances glucose oxidation and decreases fatty acid oxidation. Isolated hearts from diet rats, age-matched controls or young rats, were perfused in the working mode using the following substrates: glucose (10 mM); palmitate (1.2 mM)/3% albumin) + glucose (10 mM) (HiFA + G); palmitate (1.2 mM/3% albumin) (HiFA); palmitate (0.4 mM/3% albumin) + glucose(10 mM) (LoFA + G); palmitate (0.4 mM/3% albumin) (LoFA). Hearts were preconditioned with 3 × 5 min ischaemia/reperfusion, followed by 35 min coronary ligation and 60 min reperfusion for infarct size determination (tetrazolium method) or 20 min global ischaemia/10 or 30 min reperfusion for Western blotting (ERKp44/42, PKB/Akt). Preconditioning of glucose-perfused hearts from age-matched control (but not diet) rats reduced infarct size, activated ERKp44/42 and PKB/Akt and improved functional recovery during reperfusion (ii) perfusion with HiFA + G abolished preconditioning and activation of ERKp44/42 (iii) DCA pretreatment largely reversed the harmful effects of HiFA. Hearts from non-preconditioned diet rats exhibited smaller infarcts, but could not be preconditioned, regardless of the substrate. Similar results were obtained upon substrate manipulation of hearts from young rats. Abolishment of preconditioning in diet rats may be due to altered myocardial metabolic patterns resulting from changes in circulating FA. The harmful effects of HiFA were attenuated by stimulation of glycolysis and inhibition of FA oxidation.

The differential effects of FTY720 on functional recovery and infarct size following myocardial ischaemia/reperfusion.

AIM: The aim of this study was to evaluate the effects of the sphingosine analogue, FTY720 (Fingolimod), on the outcomes of myocardial ischaemia/reperfusion (I/R) injury. METHODS: Two concentrations of FTY720 (1 or 2.5 µM were administered either prior to (PreFTY), or following (PostFTY) 20 minutes' global (GI) or 35 minutes' regional ischaemia (RI) in the isolated, perfused, working rat heart. Functional recovery during reperfusion was assessed following both models of ischaemia, while infarct size (IFS) was determined following RI. RESULTS: FTY720 at 1 µM exerted no effect on functional recovery, while 2.5 µM significantly impaired aortic output (AO) recovery when administered prior to GI (% recovery: control: 33.88 ± 6.12% vs PreFTY: 0%, n = 6-10; p < 0.001), as well as before and after RI ( % recovery: control: 27.86 ± 13.22% vs PreFTY: 0.62% ; p < 0.05; and PostFTY: 2.08%; p = 0.0585, n = 6). FTY720 at 1 µM administered during reperfusion reduced IFS (% of area at risk (AAR): control: 39.89 ± 3.93% vs PostFTY: 26.56 ± 4.32%, n = 6-8; p < 0.05), while 2.5 µM FTY720 reduced IFS irrespective of the time of administration ( % of AAR: control: 39.89 ± 3.93% vs PreFTY: 29.97 ± 1.03% ; and PostFTY: 30.45 ± 2.16%, n = 6; p < 0.05). CONCLUSION: FTY720 exerted divergent outcomes on function and tissue survival depending on the concentration administered, as well as the timing of administration.

Melatonin receptor-mediated protection against myocardial ischaemia/reperfusion injury: role of its anti-adrenergic actions.

Melatonin has potent cardioprotective properties. These actions have been attributed to its free radical scavenging and anti-oxidant actions, but may also be receptor mediated. Melatonin also exerts powerful anti-adrenergic actions based on its effects on contractility of isolated papillary muscles. The aims of this study were to determine whether melatonin also has anti-adrenergic effects on the isolated perfused rat heart, to determine the mechanism thereof and to establish whether these actions contribute to protection of the heart during ischaemia/reperfusion. The results showed that melatonin (50 microM) caused a significant reduction in both isoproterenol (10(-7) M) and forskolin (10(-6) M) induced cAMP production and that both these responses were melatonin receptor dependent, since the blocker, luzindole (5 x 10(-6) M) abolished this effect. Nitric oxide (NO), as well as guanylyl cyclase are involved, as L-NAME (50 microM), an NO synthase inhibitor and ODQ (20 microM), a guanylyl cyclase inhibitor, significantly counteracted the effects of melatonin. Protein kinase C (PKC), as indicated by the use of the inhibitor bisindolylmaleimide (50 microM), also play a role in melatonin's anti-adrenergic actions. These actions of melatonin are involved in its cardioprotection: simultaneous administration of L-NAME or ODQ with melatonin, before and after 35 min regional ischaemia, completely abolished its cardioprotection. PKC, on the other hand, had no effect on the melatonin-induced reduction in infarct size. Cardioprotection by melatonin was associated with a significant activation of PKB/Akt and attenuated activation of the pro-apoptotic kinase, p38MAPK during early reperfusion. In summary, the results show that melatonin-induced cardioprotection may be receptor dependent, and that its anti-adrenergic actions, mediated by NOS and guanylyl cyclase activation, are important contributors.

Postconditioning the isolated working rat heart.

PURPOSE: Despite the attention focussed on postconditioning (postC; brief cycles of reperfusion/ischaemia at the onset of reperfusion, conferring cardioprotection against reperfusion injury), an infarct sparing effect for postC in the isolated working heart model has not been reported. The purpose of this study was to develop a cardioprotective postC protocol in this model. METHODS: Hearts from male Wistar rats (210-350 g) were perfused either retrogradely (Langendorff) or in the working mode. For functional studies 30 or 35 min global ischaemia (GI) and 20 or 25 min GI were applied in the Langendorff and working heart models respectively. Infarct size was measured after 35 min regional ischaemia (RI) in both models. In the latter studies hearts were subdivided into low (36.5 degrees C) and high (37 degrees C) temperature groups (during both ischaemia and initial reperfusion). In all groups hearts were either freely reperfused (nonPostC) or postconditioned (postC) by 6x10 s ischaemia/reperfusion cycles. RESULTS: In both perfusion modes postC only elicited an infarct sparing effect after a slight elevation in temperature to 37 degrees C (Langendorff: L-nonPostC=47.99+/-3.31% vs. L-postC=27.81+/-2.49%, p<0.0001; and work=W-nonPostC: 35.81+/-3.67% vs. W-postC=17.74+/-2.72%, p<0.001). However, only in the Langendorff group could postC conserve post-ischaemic function, while no significant recoveries were seen in the working hearts. CONCLUSION: We demonstrated an infarct sparing effect for postC in the working heart model, which unlike the Langendorff model, was not associated with functional preservation. The infarct sparing effect of postC in both models was however extremely sensitive to even slight fluctuations in temperature.

Efficacy of ischaemic preconditioning in the eNOS overexpressed working mouse heart model.

We recently demonstrated that exogenous nitric oxide (NO) acts as a trigger for preconditioning in the isolated rat heart model. There is however little data concerning the effects of elevated cardiac endothelial nitric oxide synthase (eNOS) expression on myocardial tolerance to ischaemia. Similarly, the effects of gender and eNOS overexpression on ischaemic preconditioning is unknown. We hypothesized that: 1) eNOS overexpression increases myocardial tolerance to ischaemia, and, 2) eNOS overexpressed hearts cannot be preconditioned, since the hearts are already maximally protected. Male and female wild-type and transgenic mice that overexpress eNOS exclusively in cardiac myocytes were perfused in the working heart mode with a modified Krebs-Henseleit buffer at a pre-load of 12.5 mm Hg and afterload of 50 mm Hg. Cardiac output, coronary flow, peak aortic systolic pressure and total work were determined before hearts were preconditioned by 4x5 min cycles of ischaemia/reperfusion, and then subjected to 20 min total global ischaemia, followed by reperfusion. Reperfusion function and myocardial infarct size were used as endpoints. Pre-ischaemic mechanical function (rate pressure product and cardiac output) was similar for wild-type and transgenic mice of both sexes. The eNOS overexpressed hearts had smaller infarcts than the hearts from their wild-type littermates (26.9+/-1.4% vs. 37.0+/-2.1% for controls, P<0.05). Preconditioning the eNOS overexpressed hearts resulted in infarct sizes comparable with control non-preconditioned hearts (27.5+/-2.0% vs. 26.9+/-1.4% for controls). Myocardial cGMP levels were elevated during sustained ischaemia in the transgenic hearts when compared with wild-type hearts (22.43+/-1.63 pmol/g ww vs 16.54+/-1.48 pmol/g ww, P<0.05). Preconditioning also elevated myocardial cGMP levels during sustained ischaemia in the wild-type hearts (26.77+/-2.81 pmol/g ww, P<0.05). We conclude that: 1) basal mechanical function is similar for both wild-type and transgenic mice of both sexes, 2) reperfusion function and infarct size was also similar for both sexes under both control conditions and after preconditioning, 3) the transgenic mice are more tolerant of ischaemia as reflected by their smaller myocardial infarcts, and, 4) the eNOS overexpressed mouse heart cannot be preconditioned regardless of whether mechanical function or infarct size is used as an end-point. These hearts may be maximally protected against ischaemia/reperfusion injury by their elevated endogenous NO levels.

Short- and long-term effects of melatonin on myocardial post-ischemic recovery.

Melatonin, the chief secretory product of the pineal gland, has been shown to protect the heart against ischemia-reperfusion injury. This was attributed to its free radical scavenging and broad-spectrum antioxidant properties. The possibility that melatonin may act via its receptor and intracellular signaling, has not yet been addressed in this regard. In all previous studies, only the acute effects of melatonin on the heart, were evaluated. The aims of the present study were to: (i) compare the acute and long-term effects of melatonin on infarct size and functional recovery of the ischemic heart, and (ii) evaluate the role of the melatonin receptor in cardioprotection. For evaluation of the short-term effects of melatonin on contractile recovery and infarct size, the isolated perfused working rat heart was subjected to 20 min global ischemia or 35 min regional ischemia respectively, and melatonin (25-50 microm) administered either before and during reperfusion, or before ischemia or during reperfusion after ischemia. The melatonin receptor was manipulated using luzindole and N-acetyltryptamine. The long-term effects of melatonin were evaluated 24 hr after melatonin administration (2.5 or 5.0 mg/kg, i.p.) or after oral administration for 7 days (20 or 40 microg/mL). Infarct size and mechanical recovery during reperfusion of the working heart were used as endpoints. Melatonin (50 microm), when administered either before and during reperfusion after ischemia or during reperfusion only, significantly improved cardiac output and work performance and reduced infarct size compared with untreated controls. Luzindole (5 microm), a melatonin receptor antagonist, abolished these cardioprotective effects. Long-term administration of melatonin (i.p. or orally for 7 days) caused a significant reduction in infarct size of hearts subjected to 35 min regional ischemia. The cardioprotection persisted for 2-4 days after discontinuation of treatment. In summary, the results obtained suggest that melatonin induces short- as well as long-term protection and that the melatonin receptor is also involved in its cardioprotective actions.

H-89, a non-specific inhibitor of protein kinase A, promotes post-ischemic cardiac contractile recovery and reduces infarct size.

Myocardial ischemia is associated with increased production of cyclic adenosine monophosphate (cAMP), with potentially deleterious effects. We hypothesized that the ischemia-induced activation of cAMP-dependent protein kinase A (PKA), could beneficially be inhibited by a PKA-inhibitor N-(2-[p-bromocinnamylamino]ethyl)-5-isoquinoline-sulfonamide (H-89). H-89 when given to isolated perfused rat hearts before 30 minutes of global ischemia-reperfusion improved postischemic function and decreased infarct size. In another series, H-89 administered prior to preconditioning by 10 minutes of transient global ischemia decreased PKA activity (measured at the end of the preconditioning protocol) and augmented postischemic mechanical recovery. H-89 given for 5 minutes before the 10 minutes of transient ischemia further decreased infarct size from 13.4 +/- 1.0% (preconditioning alone) to 7.0 +/- 0.93 (P < 0.01). In a third series, forskolin (0.3 muM, 5 minutes, 10 minutes washout prior to ischemia) increased PKA activity and reduced infarct size. Prior H-89 decreased PKA activity after 5 minutes of forskolin and further reduced infarct size versus forskolin alone. In conclusion, three procedures increased postischemic recovery and reduced infarct size: H-89; preconditioning by transient ischemia; or forskolin as a preconditioning-mimetic. PKA-inhibition by H-89 further decreased infarct size beyond preconditioning or forskolin. Despite the reservation that H-89 could be non-selective in its actions, we propose H-89 as a candidate cardioprotective agent.

The temporal relationship between p38 MAPK and HSP27 activation in ischaemic and pharmacological preconditioning.

An ischaemic preconditioning protocol and subsequent sustained ischaemia were characterized by activation and attenuation of p38 MAPK phosphorylation, respectively. However, the significance of events downstream of p38 MAPK needs investigation. Therefore the temporal relationship between phosphorylation of p38 MAPK and its downstream substrate HSP27 was studied during either an ischaemic or beta-adrenergic preconditioning protocol and during sustained ischaemia. Isolated rat hearts were preconditioned (with or without a p38 MAPK inhibitor, SB203580) with 1 x 5 min or 3 x 5 min global ischaemia or 5 min beta-adrenergic stimulation (10(-7) M isoproterenol), followed by 25 min sustained ischaemia and 30 min reperfusion. Hearts were freeze-clamped at different time intervals and fractionated to determine p38 MAPK and HSP27 phosphorylation, via Western blotting. Significant phosphorylation of cytosolic p38 MAPK and membrane (myo-fibrillar) HSP27 occurred at the end of the first preconditioning episode. However, p38 MAPK phosphorylation disappeared during subsequent preconditioning episodes, while HSP27 phosphorylation was maintained for the duration of the protocol. Similar changes in p38 MAPK and HSP27 occurred with 5 min beta-adrenergic preconditioning. After 25 min ischaemia, significant phosphorylation of cytosolic and membrane HSP27 was observed, while p38 MAPK phosphorylation was attenuated in ischaemic and beta-adrenergic preconditioned compared to non-preconditioned hearts. SB203580-induced abolishment of p38 MAPK and HSP27 phosphorylation during the triggering phase of both preconditioning protocols reversed the changes in these parameters seen after sustained ischaemia. The results suggest that p38 MAPK activation triggers HSP27 phosphorylation during both the preconditioning protocols and during sustained ischaemia. Protection of preconditioned hearts during sustained ischaemia was characterized by phosphorylation of both cytosolic and myofibrillar HSP27.

Nitric Oxide synthase (NOS) does not contribute to simulated ischaemic preconditioning in an isolated rat cardiomyocyte model.

UNLABELLED: It is widely accepted that nitric oxide (NO) is a trigger and mediator of late ischaemic preconditioning (IP), however its role in classic (protection observed within 2-4 hours after the IP stimulus) IP is less certain. In addition, the contribution of cardiomyocyte nitric oxide synthase (NOS) activation to NO production in ischaemia is unknown. The aim of this study was therefore to investigate the role of NOS, NO, reactive oxygen species (ROS) and cGMP in IP in an isolated cardiomyocyte model. METHODS: Adult rat cardiomyocytes were isolated by collagenase perfusion. Hypoxia was induced by covering pelleted cardiomyocytes with mineral oil. The IP protocol was one 10 min hypoxia/20 min reoxygenation cycle, followed by 2 hr sustained hypoxia. Non-IP cells were subjected to 2 hr sustained hypoxia only. The contribution of NO was investigated by NOS inhibition (L-NAME 50 microM) or by pre-treatment of cells with a NO donor (SNP 100 microM), and that of ROS by inclusion of ROS scavengers (MPG and N-acetyl-cysteine) or pre-treatment with H(2)O(2). End-points were cellular cGMP content and cell viability as assessed by trypan blue exclusion (TBE) and cell morphology. RESULTS: IP significantly improved myocyte viability (54% increase in TBE) at the end of sustained hypoxia. Treatment of cells with L-NAME and ROS scavengers during either the IP protocol or during sustained hypoxia had no effect on cell viability after 2 hr hypoxia, whereas viability of non-IP cells treated with L-NAME during sustained hypoxia improved significantly. cGMP levels were reduced in IP cells. Pre-treatment with SNP and H(2)O(2) did not mimic IP. CONCLUSIONS: IP conferred cardioprotection in isolated cardiomyocytes. Protection in this model was not due to activation of cardiomyocyte NOS or ROS production. However, NOS activation induced by sustained hypoxia, appeared to be harmful to non-IP cells.