Adaptation of the heart to ischemia by preconditioning: Effects on energy equilibrium,properties of sarcolemmal ATPases and release of cardioprotective proteins

Ischemic preconditioning of the heart is referred as a manifest increase in tolerance of the myocardium to otherwise damaging ischemic insult, achieved by one or few consequent initial short exposures to ischemia, each followed by reperfusion of the ischemic area. Several mechanisms such as opening of collateral vessels, the action of catecholamines, inositol phosphates, G-proteins and/or adenosine; inhibition of mitochondrial ATPase, the effects of different endogenous protective substances like heat stress or shock proteins, etc., are believed to cooperate in the mechanism of induction of preconditioning or in maintaining its effect. The present study is an attempt to extend the present knowledge about preconditioning from two aspects: i.) the peculiarities of energy equilibrium in preconditioned myocardium including adaptation of cardiac sarcolemmal ATPases to ischemia and/or hypoxia, and ii) participation of a new endogenous cardioprotective substance in the mechanism of preconditioning. The energy equilibrium in preconditioning is characterized by adaptation of cardiac energy demands to the capacity of energy production and delivery decreased by anaerobiosis and is manifested by constant ratios between ATP, ADP, AMP and the sum of ADN. Principles are proposed that may enable a prediction and mathematical modelling of the balanced energetic state in the preconditioned myocardium. These principles are based on thermodynamics and involve besides others a more economic handling of ATP by sarcolemmal ATPases. The latter enzymes adapt themselves to lowered availability of ATP by decreasing besides their Vmax also their values of K_m (increase in the affinity) for ATP and some of them even adjust their activation energy (the anaerobiosis-induced elevation of E_a.t. is missing). It was also revealed that during preconditioning several up to now not described shock proteins unlike proteins (also glycoproteins) are released from the myocardium into the coronary blood. When these proteins indicated as a HS fraction were isolated, partially purified and in concentrated form applied into the coronary circulation, they were capable to induce in preliminary experiments a cardioprotective effect resembling that of the ischemic preconditioning.     

The effects of exogenous histamine in isolated rat hearts

The role of histamine in cardiac physiology and pathophysiology is not clarified, but is dependent on species. The effects of exogenous histamine in Langendorff-perfused rat hearts were investigated. 1 mM, 100, 10, 1 and 0.1 M of histamine (n=7 each) as 15 min infusions were employed in a dose-response study, and compared to control perfused hearts (n=7). In another experimental series, 100 M histamine (n=15) was added during reperfusion after 25 min global ischemia, and compared to control ischemia-reperfusion (n=15). The maximal response to histamine in the dose-response study (100 M) was an increase of left ventricular developed pressure to 126±8% of initial value (mean±SEM, p<0.04), and increase of coronary flow to 152+6% (p<0.02) after 5 min infusion. 100 M histamine did not significantly influence heart rate or rhythm. The lowest concentration (0.1 M) did not have effects cardiac performance. Reperfusion with histamine for 2 min after ischemia reduced left ventricular developed pressure to 68±10% of initial value versus 116+17% in ischemic controls (p<0.05), and increased left ventricular end-diastolic pressure to 24±8 mmHg compared to 6±2 mmHg in controls (p<0.04). Left ventricular pressures were similar in hearts reperfused with histamine and in ischemic controls for the rest of the observation. Coronary flow increased during reperfusion in hearts given histamine. Histamine had a dose-dependent positive inotropic and vasodilatory effect in isolated rat hearts. Exogenous histamine had only minor effects on post-ischemic cardiac function.     

Histaminergic H2 Action Protects Hippocampal CA1 Neurons by Prolonging the Onset of the Anoxic Depolarization in Gerbils

Abstract: The central histaminergic action on ischemia-induced neuronal damage was examined by evaluating the histological outcome and the direct current (DC) potential shift in the hippocampal CA1 region in gerbils. An intracerebroventricular administration of histamine (10–100 nmol) improved the delayed ischemic damage in hippocampal CA1 pyramidal cells produced by 3 min of transient forebrain ischemia. A high dose (75 nmol) of mepyramine, an H₁ antagonist, aggravated ischemia-induced neuronal damage, but not a low dose (0.75 nmol). Administration of cimetidine (4 nmol) and ranitidine (3 nmol), H₂ antagonists, aggravated the neuronal damage. An injection of histamine (100 nmol) prolonged the onset time of the ischemia-induced sudden shift in the extracellular DC potential (anoxic depolarization; AD) to 133% of that in control animals. Administration of mepyramine (75 nmol) did not markedly change the AD, whereas injections of cimetidine (40 nmol) and ranitidine (3 nmol) reduced the onset latency to 47 and 45%, respectively. These findings suggest that the central H₂ action serves to protect neurons by delaying the onset of AD in gerbils.     

Brain free fatty acids, edema, and mortality in gerbils subjected to transient, bilateral ischemia, and effect of barbiturate anesthesia

Brain free fatty acids (FFAs) and brain water content were measured in gerbils subjected to transient, bilateral cerebral ischemia under brief halothane anesthesia (nontreated group) and pentobarbital anesthesia (treated group). Mortality in the two groups was also evaluated. In nontreated animals, both saturated and mono- and polyunsaturated FFAs increased approximately 12-fold in total at the end of a 30-min period of ischemia; during recirculation, the level of free arachidonic acid dropped rapidly, while other FFAs gradually decreased to their preischemic levels in 90 min. In treated animals, the levels of total FFAs were lower than the nontreated group during ischemia, but higher at 90 min of reflow, and the decrease in the rate of free arachidonic acid was slower in the early period of reflow. Water content increased progressively during ischemia and recirculation with no extravasation of serum protein, but the values were consistently lower in the treated group. None of the nontreated animals survived for 2 weeks; in contrast, survival was 37.5% in the treated group. It is suggested that barbiturate protection from transient cerebral ischemia may be mediated by the attenuation of both membrane phospholipid hydrolysis during ischemia and postischemic peroxidation of accumulated free arachidonic acid.     

Extracellular Acidic Sulfur-Containing Amino Acids and γ-Glutamyl Peptides in Global Ischemia: Postischemic Recovery of Neuronal Activity Is Paralleled by a Tetrodotoxin-Sensitive Increase in Cysteine Sulfinate in the CA1 of the Rat Hippocampus

An excessive activation of the excitatory amino acid system has been proposed as one possible mediator of the ischemia-induced delayed death of CA1 pyramidal cells in the hippocampus. Using dialytrodes in the CA1 of the rat, we have investigated multiple-unit activity and extracellular changes in acidic sulfur-containing amino acids and gamma-glutamyl peptides during ischemia (20-min, four-vessel occlusion) and during 8 h of reflow. Multiple-unit activity was abolished during ischemia and for the following 1 h, but then recovered, gradually reaching preischemic levels after 8 h of reflow. Extracellular cysteate, cysteine sulfinate, and gamma-glutamyltaurine increased (1.5- to threefold) during ischemia, and extracellular glutathione and gamma-glutamylaspartate plus gamma-glutamylglutamine increased during early reflow (two- to threefold). The recovery of neuronal activity at 4-8 h was paralleled by an increase in extracellular cysteine sulfinate (2.5-fold at 8 h of reflow). Perfusion with 10 microM tetrodotoxin at 8 h of reflow abolished the multiple-unit activity and reduced extracellular cysteine sulfinate. Considering the glutamate-like properties of cysteine sulfinate, the observed postischemic increase may be involved in the development of the delayed neuronal death.     

离体和在体大鼠心脏缺血再灌过程自由基特性的ESR研究

用ESR技术直接测定离体和在体大鼠心肌组织缺血再灌(I-R)过程中的自由基浓度。结果表明,在用无细胞K-H液灌流的离体I-R模型和在体I-R过程中,大鼠心脏结扎LAD10min再灌30s心肌组织中g=2.0015的自由基浓度均显著高于假结扎对照组。提示心脏I-R过程有大量自由基生成,且其主要来源不是白细胞。体外自由基生成系统试验结果表明,Vit C可清除O_2~ 和·OH,N-乙酰半胱氨酸(NAC)只对·OH有一定清除作用。在体结扎LAD前2min静脉注射Vit C或NAC(150mg/kg)可使再灌后心肌内短时间产生的自由基浓度降至接近假结扎组水平,说明心脏I-R过程产生的原初自由基可能以·OH和O_2~ 为主。测定心肌组织自由基信号对微波功率敏感性及信号g值特性表明了I-R过程中显著变化的信号成分主要来自碳中心有机自由基及有机过氧化自由基。它们可能是初级活性氧自由基反应的次级产物。抑制或清除初级活性氧自由基可能成为改善心脏I-R损伤的途径之一。     

Brain Cortical Fatty Acids and Phospholipids During and Following Complete and Severe Incomplete Ischemia

Abstract: To explore the possibility that peroxtdative degradation of brain tissue lipid constituents is an important mechanism of irreversible ischemic damage, we measured cortical fatty acids and phospholipids during reversible brain ischemia in the rat. Neither complete nor severe incomplete ischemia (5 and 30 min) caused any measurable breakdown of total or individual fatty acids or phospholipids. Except for a small (and reversible) decrease of inositol plus serine phosphoglycerides in the early postischemic period following 30 min of incomplete ischemia, there were no significant losses of fatty acids or phospholipids during recirculation. Since peroxidation, induced in brain cortical tissue in vitro , characteristically involves degradation of polyenoic fatty acids (arachidonic and docosahexaenoic acids) and of ethanolamine phosphoglycerides, the present in vivo results fail to support the hypothesis that peroxidation of membrane lipids is of primary importance for ischemic brain cell damage. Both complete and severe incomplete ischemia caused a similar increase in the tissue content of free fatty acids (FFA). Thus the FFA pool increased by about 10 times during a 30-min ischemic period, to constitute 1 - 2% of the total fatty acid pool. Since there was a relatively larger increase in polyenoic FFA (especially in arachidonic acid) than in saturated FFA, the release of FFA may be the result of activation of a phospholipase A₂ unbalanced by reesterification. Increased levels of FFA persisted during the initial recirculation period, but a gradual normalization occurred and the ischemic changes were essentially reversed at 30 min after restoration of circulation. The pathophysiological implications of the changes in FFA are discussed with respect to mitochondrial dysfunction, formation of cellular edema and prostaglandin-mediated deterioration of postischemic circulation.     

Barbiturate Attenuation of Brain Free Fatty Acid Liberation During Global Ischemia

Abstract: To find a biochemical basis for the increased tolerance of the brain to anoxia during barbiturate anesthesia, we studied whole-brain free fatty acids (FFA) at various times after decapitation of awake and pentobarbital-anesthetized rats. Post-decapitation, the brains were kept at 37°C for 1 to 60 min before freezing in liquid N₂. Nonischemic brains were frozen in liquid N₂, using a rapid sampling technique. Whole-brain arachidonic, stearic, oleic, linoleic, and palmitic acids were quantitated by gas-liquid chromatography. In unanesthetized, nonischemic brain, total FFA was 1226 ± 121 nmol/g brain ( n = 12) and was unaffected by pentobarbital anesthesia (1126 ± 86 nmol/g brain, n = 11), except for a reduction in arachidonic acid. Total FFA in unanesthetized and pentobarbital-anesthetized rats transiently declined between 0 and 1 min of ischemia, and then rose linearly for up to 60 min, with consistently lower values in pentobarbital-treated rats, the greatest attenuation being that of arachidonic and stearic acid liberation. Brain FFA liberation during global ischemia is the first known biochemical variable directly correlated with the duration (i.e., severity) of global ischemia. The attenuation of brain FFA liberation and especially of arachidonic and stearic acids may be the biochemical basis of barbiturate attenuation of ischemic brain injury.     

Free radical scavenging systems of rat astroglial cells in primary culture: Effects of anoxia and drug treatment

Hypoxic injury of rat astroglial cells in primary culture initiates several modifications of their functional integrity. A significant decrease of the cellular oxygen consumption was observed in astrocytes submitted to a 15 h low oxygen pressure. The addition of almitrine (dialylamino-4,6-triazinyl 2)-1-(bis-parafluorobenzydryl)-4-piperazine, a chemoreceptor agonist, restored almost completely the respiratory activity of the hypoxia treated cells. In order to test the hypothesis that oxygen free radical formation may contribute to the cellular damage resulting from ischemia, the activities of the following antioxidant enzymatic systems have been determined in the cultured astrocytes: Cu,Zn-and Mn-superoxide dismutase (SOD), glutathione peroxidase (GSH-PX), glutathione reductase (GSH-RED), and catalase (CAT). Only a significant and specific decrease of the Mn-SOD activity was observed after the hypoxia-normoxia exposure. The other oxygen radical scavenging systems were not modified. The addition of almitrine antagonized the decrease of the Mn-SOD activity observed in the low oxygen pressure treated cells, but results clearly point-out the importance of oxygen radical production in the astroglial response after hypoxic injury. A beneficial effect of almitrine toward the observed alteration has been underlined. It is suggested that some mitochondrial alterations could be related to some aspects of theastroglial hypoxic stress.