Role of catalase in myocardial protection against ischemia in heat shocked rats

Heat Shock Proteins in Oxidative Stress and Ischemia/Reperfusion Injury and Benefits from Physical Exercises: A Review to the Current Knowledge

Heat shock proteins (HSPs) are molecular chaperones produced in response to oxidative stress (OS). These proteins are involved in the folding of newly synthesized proteins and refolding of damaged or misfolded proteins. Recent studies have been focused on the regulatory role of HSPs in OS and ischemia/reperfusion injury (I/R) where reactive oxygen species (ROS) play a major role. ROS perform many functions, including cell signaling. Unfortunately, they are also the cause of pathological processes leading to various diseases. Biological pathways such as p38 MAPK, HSP70 and Akt/GSK-3β/eNOS, HSP70, JAK2/STAT3 or PI3K/Akt/HSP70, and HSF1/Nrf2-Keap1 are considered in the relationship between HSP and OS. New pathophysiological mechanisms involving ROS are being discovered and described the protein network of HSP interactions. Understanding of the mechanisms involved, e.g., in I/R, is important to the development of treatment methods. HSPs are multifunctional proteins because they closely interact with the antioxidant and the nitric oxide generation systems, such as HSP70/HSP90/NOS. A deficiency or excess of antioxidants modulates the activation of HSF and subsequent HSP biosynthesis. It is well known that HSPs are involved in the regulation of several redox processes and play an important role in protein-protein interactions. The latest research focuses on determining the role of HSPs in OS, their antioxidant activity, and the possibility of using HSPs in the treatment of I/R consequences. Physical exercises are important in patients with cardiovascular diseases, as they affect the expression of HSPs and the development of OS.

Whole-body heat shock protects the ischemic rat heart by stimulating mitochondria respiration

Whole-body heat shock (HS) leads to an enhancement of postischemic mechanical function and an improvement in glucose use by the rat heart. Here, we examine the effect of HS on isolated mitochondrial metabolism during reperfusion in the working rat heart. Rats were anesthetized, and their body temperature was raised to 41-42 degrees C for 15 min. Control rats were treated the same way but were not exposed to hyperthermia. Twenty-four hours after HS or sham treatment, rats were reanesthetized and the hearts were removed for perfusion with Krebs-Henseleit buffer, containing 11 mmol glucose/L and 1.2 mmol palmitate/L prebound to 3% albumin. Hearts were subjected to 25 min of global ischemia followed by 30 min of reperfusion. At the end of reperfusion, heart mitochondria were isolated using differential centrifugation and respiration measured in the presence of pyruvate, glutamate, or palmitoylcarnitine. Hearts subjected to HS showed an enhanced recovery of function, expressed as aortic flow, during the reperfusion period, compared with sham hearts. This improved functional status was associated with a significant increase in state 3 respiration in the presence of pyruvate, glutamate, or palmitoylcarnitine. These results show that HS offers protection against ischemic damage, and that a possible mechanism might be the enhanced myocardial metabolism of fuels.

PREVIOUS HEAT SHOCK TREATMENT ATTENUATES LIPOPOLYSACCHARIDE-INDUCED HYPORESPONSIVENESS OF PLATELETS IN RATS

Several studies demonstrated that previous heat shock treatment caused expression of heat shock proteins (HSPs) and reduced organ dysfunction and mortality in experimentally induced severe sepsis. However, the protective mechanism on platelet function remains unclear. The aim of this study was to investigate the effect of heat shock treatment on platelet aggregation ex vivo in endotoxin-induced rats with sepsis. Rats of the heated group were heated by whole-body hyperthermia 18 h before lipopolysaccharide (LPS) injection. Blood samples were obtained from the carotid artery 90 min after LPS injection. Platelet aggregation ability was measured by aggregometer. Results revealed that platelet aggregation ex vivo was significantly inhibited in LPS-induced rats in a manner of dose dependence. Previous heat shock treatment caused overexpression of HSPs and significantly attenuated the LPS-induced platelet hyporesponsiveness. This attenuation disappeared in accordance with absence of HSP72 at 7 days after heat shock treatment. Aggregation of normal platelets was also inhibited by incubating with plasma obtained from endotoxemic rats but not from preheated endotoxemic rats. Furthermore, no significant hyporesponsiveness was found in endotoxemic platelets in addition to preheated endotoxemic plasma. The addition of H2O2 scavenger catalase diminished the platelet hyporesponsiveness significantly only in nonheated endotoxemic rats. Moreover, the plasma nitrite and nitrate levels were significantly attenuated in preheated endotoxemic rats. These results revealed that previous heat shock treatment might attenuate LPS-induced hyporesponsiveness of platelets by changing the plasma components possibly through altering H2O2 and nitric oxide concentrations.

Heat shock proteins and cardiovascular pathophysiology

In the eukaryotic cell an intrinsic mechanism is present providing the ability to defend itself against external stressors from various sources. This defense mechanism probably evolved from the presence of a group of chaperones, playing a crucial role in governing proper protein assembly, folding, and transport. Upregulation of the synthesis of a number of these proteins upon environmental stress establishes a unique defense system to maintain cellular protein homeostasis and to ensure survival of the cell. In the cardiovascular system this enhanced protein synthesis leads to a transient but powerful increase in tolerance to such endangering situations as ischemia, hypoxia, oxidative injury, and endotoxemia. These so-called heat shock proteins interfere with several physiological processes within several cell organelles and, for proper functioning, are translocated to different compartments following stress-induced synthesis. In this review we describe the physiological role of heat shock proteins and discuss their protective potential against various stress agents in the cardiovascular system.

Mitogen-activated protein kinases mediate heat shock-induced delayed protection in mouse heart

We determined the role of p38 mitogen-activated protein kinase (MAPK), 72-kDa heat shock protein (HSP72), and antioxidant enzymes in whole body heat stress (HS)-induced cardioprotection in mouse hearts. Adult male mice were treated with either HS or anesthesia only. At 0.5, 48, 72, or 120 h later, the hearts were subjected to 20 min of global ischemia and 30 min of reperfusion in Langendorff mode. A significant protection against ischemia-reperfusion injury was observed 48 h after HS as demonstrated by: 1) reduction in infarct size; 2) decrease in leakage of lactate dehydrogenase; and 3) enhanced postischemic ventricular contractile function. No such protection was observed at other post-HS time points. HS caused an ~25% increase in phosphorylated c-Jun NH2-terminal kinase (JNK) but not p38 MAPK in the heart during the first 2-h post-HS time period. Cardioprotection was abolished by the MAPK inhibitor SB-203580, which also partially suppressed the HS-induced JNK phosphorylation. The protective effect was associated with a two- to threefold increase in HSP72 protein accumulation, but not antioxidant enzyme activities (catalase and Cu/Zn and Mn SOD) in the myocardium. Although HSP72 levels remained high 72 h after HS, the cardioprotection had already disappeared. We conclude that HS induces a transient delayed cardioprotection at 48 h after thermal stress in mice which appears to be mediated via a MAPK-signaling pathway.

Polyamine oxidase activity in lymphoid tissues of glucocorticoid-treated rats

Glucocorticoids are known to negatively affect lymphoid tissues, in which they cause programmed cell death. Polyamine depletion, which occurs in glucocorticoid-treated animals by inhibition of biosynthesis and induction of acetylation, may represent a signal to thymocytes for progression into the apoptotic program. Since catalysis of polyamines by the catabolic pathway produces hydrogen peroxide as a by-product, it has been suggested that the apoptotic process may be, in part, due to oxidative stress as a result of hydrogen peroxide production. In order to verify whether polyamine oxidase (EC 1.5.3.11) may play a role in the process, we examined the activity of the enzyme in the thymus and spleen of glucocorticoid-treated rats. We administered dexamethasone (4 mg/kg) or two different doses of corticosterone (4 mg/kg or 30 mg/kg) to rats, which were killed 8 or 24 hr after hormone injection. We found that corticosterone and dexamethasone affected polyamine oxidase activity in both tissues, with an opposite dose-dependent effect of the natural hormone in the thymus. The decrease and increase in polyamine oxidase after the two doses of corticosterone were correlated with the absence and the occurrence of DNA fragmentation, respectively. Moreover, corticosterone affected polyamine oxidase activity earlier (8 hr) than dexamethasone (24 hr), but the synthetic hormone was more efficient than the natural hormone in thymic polyamine depletion. The polyamine oxidase response may represent an important event in lymphoid tissues after glucocorticoid treatment, suggesting a role of the enzyme in the catabolic effects exerted by the two hormones.

Myocardial self-preservative effect of heat shock protein 70 on an immature lamb heart

BACKGROUND

Heat shock proteins have been shown to enhance myocardial tolerance of ischemia-reperfusion injury and are induced in the myocardium of many animals by various stressors.

METHODS

To assess the effects and time course of the inducible form of heat shock protein 70, we raised the rectal temperature of 15 neonatal lambs to 43 degrees C for 15 minutes. At 15, 30, 60, and 120 minutes and 24 hours after heat shock, hearts were subjected to immunoblot analysis for heat shock protein (hsp 72/73). Twenty-four hours after heat shock, neonatal lamb hearts (n = 8) were subjected to 2 hours of cold cardioplegic ischemia (HSP group). Eight neonatal lamb hearts without heat shock served as control. After 60 minutes of reperfusion, left ventricular systolic and diastolic function, coronary blood flow (CBF), myocardial oxygen consumption (MVO2), and lactate levels were measured. Endothelial function was assessed by measuring in situ coronary vascular resistance response to acetylcholine and trinitroglycerine.

RESULTS

The HSP group showed a significantly higher recovery of systolic function as well as MVO, and a lower lactate level compared to the control group at 60 minutes after reperfusion. Recovery of coronary endothelial function was also significantly better in the HSP group than in the control group. Inducible form of HSP 70 was expressed 15 minutes after heat shock and continued to be observed at 24 hours after the stress.

CONCLUSIONS

Heat shock stress associated with the production of inducible heat shock proteins improved the recovery of ventricular function as well as endothelial function and aerobic metabolism after hypothermic cardioplegic ischemia. Induction of heat shock proteins by any means prior to planned hypothermic ischemia may lead to a new approach for myocardial protection.

Cardiac adaptation to ischemia-reperfusion injury

Acute myocardial ischemia initiates a cascade of cellular events that lead to irreversible injury. We previously described the transient nature of heat-shock induced cardioprotection; treatment with a catalase inhibitor abolished the cytoprotective actions without affecting expression levels of HSP71. Repeated, transient ischemic episodes augment the ischemic tolerance of affected myocardium but the fundamental cytoprotective mechanism(s) for both "early" and "delayed" preconditioning remains unclear. Increased cellular induction of protooncogenes, heat shock genes, and downstream effector proteins might play critical roles in the cytoprotection afforded by delayed preconditioning. We measured c-fos, c-jun, c-myc, and hsp70 induction in preconditioned (2 x 5-min ischemia/10-min reperfusion) and control rabbit hearts that either underwent 30- or 120-min coronary occlusion and 60-min reperfusion, or did not undergo subsequent sustained ischemia; the latter hearts were allowed to recover for 0, 1, 3, 6, 24, 48, 72, or 96 hours. Both c-fos and c-jun in ischemic tissue were strongly induced by ischemia-reperfusion injury and preconditioning pretreatment. However, expression levels diminished significantly by 1-h reperfusion and remained depressed during the 96-h recovery period. Hsp70 (inducible) mRNA expression levels were highest primarily in ischemic myocardium after 6-h recovery post-preconditioning; Hsp70 levels in ischemic myocardium were slightly stronger after 48-h recovery but subsequently diminished to barely detectable levels by 96-h post-preconditioning. Induction of c-fos and c-jun preceded that of Hsp70. These findings support the concept that upregulation of immediate early genes and heat shock genes plays an important role in myocardial adaptation to acute ischemic stress.

Role of protein kinase C and 72 kDa heat shock protein in ischemic tolerance following heat stress in the rat heart

Heat stress (HS) and the subsequent expression of 72 kDa heat shock protein (HSP 72) has been shown to enhance post-ischemic functional recovery and reduce infarct size. Because the synthesis of heat shock proteins involves activation of heat shock transcription factors through phosphorylation, we hypothesized that inhibition of protein kinase C (PKC) would block HS mediated protection and expression of HSP 72 in the heart. Five groups of rats were studied (1) Sham anesthetized, (2) HS group--animals were heat shocked by raising the whole body core temperature to 42 degrees C for 15 min, (3) Vehicle group--HS rats treated with 50% DMSO in saline, (4) PKC inhibitor-treated group--specific PKC antagonist, chelerythrine chloride (5 mg/kg, i.p) given 30 min prior to HS and (5) Vehicle treated control--non-HS rats treated with vehicle prior to ischemia/reperfusion. Hearts were subjected to 30 min of regional ischemia and 90 min of reperfusion 24 h after HS. Risk area was delineated by injection of 10% Evan's blue and infarct size determined using computer morphometry of tetrazolium stained sections. Infarct size (% area at risk) reduced significantly from 49.4 +/- 2.3% (n = 7) in sham to 10.0 +/- 2.5% (p < 0.01) and 9.1 +/- 3.0% in HS and vehicle treated HS groups respectively (p < 0.05) Treatment with chelerythrine prior to HS increased infarct size to 49.4 +/- 2.3% (p < 0.05). Infarct size in chelerythrine-treated non-HS ischemic/reperfused heart was 40.7 +/- 5.4%, which did not differ significantly from vehicle-treated sham group. Western blot analysis demonstrated marked increase in HSP 72 in HS groups (with or without vehicle treatment) and pretreatment with chelerythrine chloride failed to inhibit the expression of HSP 72. The results suggest that HS-induced ischemic tolerance is mediated via PKC pathway and this protection does not appear to be directly related to the expression of HSP 72 in rat heart.

Gene transfer of heat shock protein 70 protects lung grafts from ischemia-reperfusion injury

BACKGROUND

We recently demonstrated that heat stress induction of heat shock protein 70 (HSP70) in donor animals before harvest decreases posttransplant ischemia-reperfusion injury in preserved rat lung isografts. The purpose of this study was to investigate the feasibility of HSP70 gene transfection into rat lung isografts using an adenoviral vector, and to study the effects of gene expression on subsequent ischemia-reperfusion injury.

METHODS

In preliminary studies to determine the optimal titer, animals were injected with various titers of adenovirus-HSP70 (saline, 5 x 10(9), 1 x 10(10), and 2 x 10(10) plaque forming units [pfu]) and sacrificed 5 days after injection. To determine the optimal exposure time, animals were sacrificed at different times (0, 6, 24, and 72 hours) after intravenous injection of adenovirus-HSP70. In a subsequent series of transplant experiments, donors were allocated to three groups according to transfection strategy. Group 1 (n = 8) donors received 5 x 10(9) pfu adenovirus-HSP70 intravenously, group 2 (n = 7) donors received 5 x 10(9) pfu adenovirus-beta-galactosidase (as a virus control), and group 3 (n = 7) donors received saline and served as a negative control. Twenty-four hours after treatment all grafts were harvested and stored for 18 hours before orthotopic left lung transplantation. Twenty-four hours after implantation animals were sacrificed for assessment. The expression of HSP70 was assessed by Western blot analysis.

RESULTS

In preliminary studies, HSP70 was detectable even at low titers (5 x 10(9) pfu) of adenovirus-HSP70, and was detectable at low levels as early as 6 hours after intravenous administration. Heat shock protein 70 expression was maximal at 24 hours. In transplant experiments, Western blot analysis showed that overexpression of HSP70 occurred in the HSP70-transfected lungs. The mean arterial oxygenation 24 hours after reperfusion in group 1 was superior in comparison with other groups (p < 0.05). Wet to dry weight ratio (p < 0.05) and myeloperoxidase activity (p < 0.05) were also significantly less in group 1 grafts compared with the other groups.

CONCLUSIONS

This study demonstrates that in vivo, donor adenovirus-mediated gene transfer of HSP70 decreases subsequent ischemia-reperfusion injury in rat lung isografts.

Heat stress proteins and myocardial protection: experimental model or potential clinical tool?

Heat stress proteins (hsp) are induced by a variety of stimuli including elevated temperature, ischaemia, hypoxia, pressure overload and some chemicals. They help to maintain the metabolic and structural integrity of the cell, as a protective response to external stresses. They are known to protect the myocardium from the damaging effects of ischaemia and reperfusion. The heat stress response results in accumulation of heat stress proteins. The beneficial effects associated with their expression include improved endothelial and mechanical recovery of the ischaemic heart. In addition, preservation of high energy phosphates and reduction in infarct size. It has also been shown that critical amounts of hsp70 are necessary to ensure protection of the myocardium. However, questions remain regarding the biochemical mechanisms underlying this protective effect. Alterations in the cell metabolism and chaperone function of cells expressing heat shock proteins, are thought to be responsible. Despite the obvious clinical benefits related to the heat stress response in a clinical setting, the application of this phenomena remains limited. Heat, both quantitatively and qualitatively is one of the best inducers of heat stress proteins. However, the effects of heat stress are nonspecific and intracellular damage is a common occurrence. The search for alternative stimuli, particularly within the fields of pharmacotherapy or genetic manipulation may offer more viable options, if the heat stress response is take its place as an established strategy for myocardial protection.

Antimony-induced alterations in thiol homeostasis and adenine nucleotide status in cultured cardiac myocytes

Cultured cardiac myocytes were exposed for up to 4 h to 50 and 100 microM potassium antimonyl tartrate (PAT). After 4 h, 50 and 100 microM PAT killed 14 and 33% respectively of the cardiac myocytes. PAT-induced alterations in both protein and nonprotein thiol homeostasis. Transient increases in oxidized glutathione disulfide (GSSG) levels were detected after cells were treated with 100 microM PAT for 2 h. After 4 h, both concentrations of PAT significantly depleted reduced glutathione (GSH) levels. Protein thiols levels were also decreased after a 2-h exposure to 50 and 100 microM PAT. Cells treated with 50 microM and 100 microM PAT had a 15% and 40% reduction respectively in protein thiols after 4 h. PAT also significantly inhibited glutathione peroxidase and pyruvate dehydrogenase activity in cardiac myocytes. Pyruvate dehydrogenase activity levels were inhibited as early as 1 h after cells were treated with both concentrations of PAT. Cardiac myocyte ATP levels were also decreased by PAT, but only after a 4-h exposure to 50 microM and 100 microM PAT. Decreases in cellular ATP levels paralleled PAT toxicity put appeared to be secondary to other cellular changes initiated by PAT exposure.

In vivo gene transfection with heat shock protein 70 enhances myocardial tolerance to ischemia-reperfusion injury in rat

Heat shock protein 70 (HSP70) has been reported to be involved in the myocardial self-preservation system. To obtain the evidence that HSP70 plays a direct role in the protection from myocardial ischemia-reperfusion injury, rat hearts were transfected with human HSP70 gene by intracoronary infusion of hemagglutinating virus of Japan (HVJ)-liposome containing human HSP70 gene. The control hearts were infused with HVJ-liposome without the HSP70 gene. The hearts from whole-body heat-stressed or nontreated rats were also examined. Western blot and immunohistochemical analysis showed that apparent overexpression of HSP70 occurred in the gene transfected hearts and that gene transfection might be more effective for HSP70 induction than heat stress. In Langendorff perfusion, better functional recovery as well as less creatine phosphokinase leakage after ischemia were obtained in the gene transfected hearts with HSP70 than in the control or nontreated hearts. Furthermore, the gene transfected hearts showed better functional recovery than the heat-stressed hearts. These results indicated that overexpressed HSP70 plays a protective role in myocardial injury, suggesting the possibility that gene transfection with HSP70 may become a novel method for myocardial protection through enforcing the self-preservation systems.