Specific and sustained down-regulation of genes involved in fatty acid metabolism is not a hallmark of progression to cardiac failure in mice.

Preferential and specific down-regulation of genes involved in fatty acid (FA) uptake and metabolism is considered a hallmark of severe hypertrophic remodeling and progression to cardiac failure. Therefore, we investigated the time course of changes in cardiac metabolic gene expression (1) in mice subjected to regional myocardial infarction (MI) for 4 days, 1 month, or 3 months and (2) in mice overexpressing calcineurin (Cn) which initially develop concentric hypertrophy progressing after the age of 4 weeks to dilated cardiomyopathy and failure. In both models, hypertrophy was characterized by increased expression of beta-myosin heavy chain protein and atrial natriuretic factor mRNA, indicative of marked structural remodeling. Fractional shortening progressively decreased from 31% to 15.1% and 3.7% 1 and 3 months after MI, respectively. One month post-MI, the expression of several metabolic genes, i.e., acyl-CoA synthetase (-50%), muscle-type carnitine palmitoyl transferase 1 (-37%) and citrate synthase (-28%), was significantly reduced in the surviving myocardium. Despite overt signs of cardiac failure 3 months post-MI, the expression of these genes had returned to normal levels. In hearts of both 4- and 6-week-old Cn mice, genes involved in both FA and glucose metabolism and mitochondrial citrate synthase were down-regulated, reflecting an overall decline in metabolic gene expression, rather than a specific and preferential down-regulation of genes involved in FA uptake and metabolism. These findings challenge the concept that specific and sustained down-regulation of genes involved in FA uptake and metabolism represents a hallmark of the development of cardiac hypertrophy and progression to failure.

Functional and metabolic adaptation of the heart to prolonged thyroid hormone treatment.

In heart failure, thyroid hormone (TH) treatment improves cardiac performance. The long-term effects of TH on cardiac function and metabolism, however, are incompletely known. To investigate the effects of up to 28 days of TH treatment, male Wistar rats received 3,3',5-triiodo-l-thyronine (200 microg/kg sc per day) leading to a 2.5-fold rise in plasma fatty acid (FA) level and progressive cardiac hypertrophy (+47% after 28 days) (P < 0.001). Ejection fraction (echocardiography) was increased (+12%; P < 0.05) between 7 and 14 days and declined thereafter. Neither cardiac FA oxidation, glycolytic capacity (homogenates) per unit muscle mass, nor mRNA levels of proteins involved in FA and glucose uptake and metabolism (Northern blots and microarray) were altered. After 28 days of treatment, mRNA levels of uncoupling proteins (UCP) 2 and 3 and atrial natriuretic factor were increased (P < 0.05). This indicates that TH-induced hypertrophy is associated with an initial increase in cardiac performance, followed by a decline in cardiac function and increased expression of UCPs and atrial natriuretic factor, suggesting that detrimental effects eventually prevail.

Fasting-induced changes in the expression of genes controlling substrate metabolism in the rat heart.

During fasting, when overall metabolism changes, the contribution of glucose and fatty acids (FA) to cardiac energy production alters as well. Here, we examined if the heart is able to adapt to such fasting-induced changes by modulation of its gene expression. Rats were fed ad libitum or fasted for 46 h, resulting in reduced circulating glucose levels and a 3-fold rise in FA. Besides changes in the cardiac activity or content of proteins involved in glucose or FA metabolism, mRNA levels also altered. The cardiac expression of genes coding for glucose-handling proteins (glucose transporter GLUT4, hexokinase I and II) was up to 70% lower in fasted than in fed rats. In contrast, the mRNA levels of various genes involved in FA transport and metabolism (FA translocase/CD36, muscle-type carnitine palmitoyl transferase 1, long-chain acyl-CoA dehydrogenase) and of the uncoupling protein UCP-3 increased over 50% in hearts of fasted rats. Surprisingly, mRNA levels of the fatty acid- activated transcription factors PPARalpha and PPARbeta/delta were reduced in hearts of fasted rats, whereas in livers, fasting led to a marked rise in PPARalpha mRNA. Reducing FA levels by nicotinic acid administration during the final 8 h of fasting did not affect the expression of the majority of metabolic genes, but totally abolished the induction of UCP-3. In conclusion, the adult rat heart responds to changes in nutritional status, as provoked by 46 h fasting, through adjustment of glucose as well as FA metabolism at the level of gene expression.

Effects of fatty acids on uncoupling protein-2 expression in the rat heart.

Fatty acids are thought to play a role in the activity of uncoupling proteins (UCP) and have been shown to regulate the expression of genes encoding proteins involved in fatty acid handling. Therefore, we investigated whether fatty acids, which are the main substrates for the heart, affect rat cardiac UCP-2 expression in vivo and in vitro. After birth, when the contribution of fatty acid oxidation to cardiac energy conversion increases, UCP-2 expression enhanced rapidly. In the adult heart, however, UCP-2 mRNA levels did not alter during conditions associated with either enhanced (fasting, diabetes) or decreased (hypertrophy) fatty acid utilization. Exposure of neonatal cardiomyocytes and embryonic rat heart-derived H9c2 cells to fatty acids (palmitic and oleic acid) for 48 h strongly induced UCP-2 expression. Stimulation of neonatal cardiomyocytes with triiodothyronine also increased UCP-2 mRNA levels, though only in the presence of fatty acids. Ligands specific to the fatty acid-activated transcription factor PPARalpha, but not to PPARgamma, acted as inducers of cardiomyocyte UCP-2 expression. It is concluded that fatty acids promote UCP-2 expression in neonatal cardiomyocytes, which might explain the rapid increase in UCP-2 mRNA in the postnatal heart. However, UCP-2 mRNA levels in the adult heart appear to be insensitive to changes in cardiac fatty acid handling under various pathological conditions.

Long-chain fatty acid-induced changes in gene expression in neonatal cardiac myocytes.

Long-chain fatty acids are the most important substrates for the heart. In addition, they have been shown to affect signalling pathways and gene expression. To explore the effects of long-chain fatty acids on cardiac gene expression, neonatal rat ventricular myocytes were cultured for 48 h with either glucose (10 mm), fatty acids (palmitic and oleic acid, 0.25 mm each), or a combination of both as exogenous substrates. Exposure to fatty acids (both in the absence or presence of glucose) neither affected cellular morphology and protein content nor induced alterations in the expression of phenotypic marker genes like atrial natriuretic factor and the Ca-ATPase SERCA2. However, incubation with fatty acids (with or without glucose) resulted in up to 4-fold increases of the mRNA levels of fatty acid translocase (FAT/CD36), heart-type fatty acid-binding protein, acyl-CoA synthetase, and long-chain acyl-CoA dehydrogenase. In contrast, the expression of genes coding for proteins involved in glucose uptake and metabolism, i.e., glucose transporter GLUT4, hexokinase II, and glyceraldehyde 3-phosphate dehydrogenase, remained constant or even declined under these conditions. These changes corresponded with a 60% increase in cardiomyocyte fatty acid oxidation capacity. Interestingly, the peroxisome proliferator-activated receptor-alpha (PPARalpha)-ligand Wy 14,643, but not the PPARgamma-ligand ciglitazone, also resulted in increased mRNA levels of genes involved in fatty acid metabolism. In conclusion, fatty acids specifically and co-ordinately up-regulate transcription of genes coding for proteins involved in cardiac fatty acid transport and metabolism, most likely through activation of PPARalpha.

Co-expression in rat heart and skeletal muscle of four genes coding for proteins implicated in long-chain fatty acid uptake.

It has been suggested that specific membrane-associated and cytoplasmic proteins cooperate in the uptake of long-chain fatty acids by cardiac and skeletal muscle cells. A prerequisite for this hypothesis would be the co-occurrence of these proteins in muscle. Thus, we studied the possible co-expression in rat muscles of the genes coding for the integral membrane proteins fatty acid transport protein (FATP) and fatty acid translocase (FAT), the membrane-associated plasmalemmal fatty acid-binding protein (FABPpm) and the cytoplasmic heart-type fatty acid-binding protein (H-FABPc). The transcripts of the four proteins were assessed in heart and skeletal muscles of adult Wistar rats, in isolated cells and cell lines from rat heart and also in rat heart during development and upon streptozotocin-induced diabetes. All four genes showed high expression levels in heart, somewhat lower in red skeletal muscle (soleus) and appreciably lower in white skeletal muscle (extensor digitorum longus). FATP, FAT and H-FABPc showed a 3- to 5-fold increase in mRNA expression during maturational growth of the heart, while the FABPpm expression remained virtually constant. In the heart, streptozotocin-diabetes induced a slight, but statistically not significant, increase in the expression of all four genes. In conclusion, this study shows the co-expression of FATP, FAT, FABPpm and H-FABPc in rat muscles. This finding supports the possible cooperation of these proteins in the uptake of long-chain fatty acids by muscle cells.

Cloning and cellular distribution of a group II phospholipase A2 expressed in the heart.

Phospholipase A2 has been considered to play a role in physiological membrane turnover in cardiac tissue and in the degradation of membrane lipids under pathophysiological conditions, such as ischemia and reperfusion. We report the cloning of a cDNA encoding a member of the Ca2+-dependent, low molecular mass phospholipase A2 (PLA2) present in rat heart. The cDNA predicts a mature protein of 146 amino acid residues including a 21 amino acid sequence at the N-terminal end, which has the features characteristic of eukaryotic secretory signal peptides. The deduced amino acid sequence constitutes an enzyme of the group II class of PLA2s, and resembles PLA2s from other mammalian sources. A Northern blot analysis performed to determine the tissue distribution showed that rat ileum contains the largest amount of the PLA2 transcript among the tissues examined, a weaker signal was present in heart, spleen and soleus muscle, and no signal could be detected in EDL muscle, stomach, liver, kidney, brain and lung. Northern blot analysis and reverse transcriptase-polymerase chain reaction (RT-PCR) techniques indicate the presence of this enzyme in neonatal and adult rat cardiomyocytes and in a cultured rat cardiac fibroblast-like cell line, but not in rat cardiac-derived endothelial cell lines. Transcription levels of rat heart group II PLA2 in isolated neonatal rat cardiomyocytes were found to increase after stimulating the cells with tumor necrosis factor-alpha (TNF-alpha) or the alpha1-adrenergic agonist phenylephrine.

Putative membrane fatty acid translocase and cytoplasmic fatty acid-binding protein are co-expressed in rat heart and skeletal muscles.

A membrane protein (FAT) homologous to CD36 has recently been implicated in the binding and transport of long-chain fatty acids (FA). Expression of this protein in rat heart, skeletal muscles and in isolated cardiac cells was studied. Changes in expression during development of the heart were also examined. Expression of FAT was compared to that of the cytoplasmic fatty acid-binding protein (H-FABP) to determine whether coexpression, indicative of related biological functions, could be demonstrated. FAT and H-FABP mRNAs showed a similar muscle tissue distribution and similar cellular localization in the heart. During development, heart mRNA levels for both proteins were upregulated in the same way. In conclusion, expression of FAT and H-FABP in muscle tissues and cell-types with high FA metabolism and the upregulation of mRNA levels associated with heart development, when FA utilization increases, support the suggested role of both proteins in FA metabolism.

Differences in ischaemia tolerance between hypertrophied hearts of adult and aged spontaneously hypertensive rats.

OBJECTIVE: The aim was to examine differences between the postischaemic functional and biochemical recovery of adult and aged hypertrophied hearts. METHODS: Isolated hypertrophied hearts of adult and aged spontaneously hypertensive rats (SHRadult; SHRaged) and normal hearts of age matched Wistar-Kyoto rats (WKYadult; WKYaged) were perfused in an ejecting heart preparation. Haemodynamic function was monitored before and after 45 min of ischaemia. Coronary effluent samples and tissue biopsies were taken for biochemical analysis. RESULTS: After ischaemia, in SHRadult and WKYadult the maximum positive first derivative of the left ventricular pressure (dP/dtmax) was restored to 105% and 97% respectively of the preischaemic values. Left ventricular developed pressure recovered to 80% (SHRadult) and 97% (WKYadult), while cardiac output reached 71% (SHRadult) and 99% (WKYadult) of preischaemic levels. In SHRaged and WKYaged the dP/dtmax recovered to 26% and 60% respectively (both p < 0.05 compared to the preischaemic values). The left ventricular developed pressure recovered to 36% in SHRaged and to 73% in WKYaged (both p < 0.05), while cardiac output was restored to 6% in SHRaged and 38% in WKYaged (both p < 0.05). Throughout reperfusion, left ventricular end diastolic pressure remained significantly elevated in SHRaged, and was associated with a prominent subendocardial underperfusion, suggesting an impaired diastolic functional recovery. Overall haemodynamic recovery was significantly better in the WKYaged than in the SHRaged. The preischaemic total adenine nucleotides content was comparable in all groups, but creatine phosphate levels were significantly lower in both aged groups than in adult groups. In all but the WKYadult, the total adenine nucleotides were depressed upon reperfusion, while creatine phosphate normalised, except in SHRaged. SHRaged lost more lactate dehydrogenase and tended to lose more xanthine and uric acid than other groups. CONCLUSIONS: The aged hypertrophied heart shows a higher vulnerability to ischaemic damage than the adult hypertrophied heart. This phenomenon is associated with subendocardial underperfusion, increased membrane damage and inadequate recovery of creatine phosphate levels.

Substrate-induced changes in the lipid content of ischemic and reperfused myocardium. Its relation to hemodynamic recovery.

To investigate the effect of lactate, pyruvate, and glucose on the endogenous levels of lipids in the normoxic, ischemic, and reperfused myocardium, isolated working rat hearts were exposed to various grades of ischemic insult (15, 30, or 45 minutes). Glucose was present as the basal substrate in the perfusion medium, and lactate (5 mM) or pyruvate (5 mM) was added as the cosubstrate. Lipid metabolism was evaluated by fatty acid accumulation, triacylglycerol turnover, and phospholipid homeostasis. Exogenous lactate significantly increased fatty acid content above preischemic levels after 45 minutes of ischemia. In glucose-perfused hearts, fatty acid levels were even slightly higher than in lactate-perfused hearts, whereas pyruvate-perfused hearts demonstrated less accumulation of fatty acids. By reperfusion, fatty acid levels in glucose-perfused hearts returned to control values. In lactate- and pyruvate-perfused hearts, fatty acid accumulation was further enhanced by reperfusion. When the fatty acid content exceeded 400 nmol/g dry wt during reperfusion, hemodynamic function was impaired, whereas fatty acid levels below 400 nmol/g dry wt did not correlate with hemodynamic recovery. The total triacylglycerol content did not change during ischemia and reperfusion. However, accumulation of glycerol was remarkable during the first 15 minutes of ischemia in all hearts, and release of glycerol by reperfusion was considerable in lactate-perfused hearts after 30 minutes of ischemia and in all groups of hearts after 45 minutes of ischemia. Release of glycerol in association with maintained levels of triacylglycerols suggests turnover of the triacylglycerol pool. The rate of triacylglycerol cycling correlated poorly with hemodynamic recovery. Accumulation of arachidonic acid revealed disturbances in phospholipid turnover. Arachidonic acid accumulation during reperfusion demonstrated a strong relation with impairment of cardiac function. Hence, derangements in phospholipid homeostasis during reperfusion might be involved in myocardial damage, which is influenced by the substrates available.

Arachidonic acid incorporation in cardiomyocytes, endothelial cells and fibroblast-like cells isolated from adult rat heart.

The incorporation of radiolabeled arachidonic acid (3[H]-AA) in normoxic cardiomyocytes (MC), cardiac endothelial cells (EC) and fibroblast-like cells (FL) isolated from adult rat heart was studied. Deposition of 3[H]-AA in the cellular lipid pool was assessed with biochemical and autoradiographic techniques. Extraction and subsequent analysis of lipids from the three different cell types revealed that MC contained significantly more triacylglycerols than EC and FL. The proportion of (unlabeled) AA was also higher in MC triacylglycerols than in EC and FL. The quantity of phospholipids did not differ among the three cell types studied. However, the content of (unlabeled) AA in the MC phospholipid pool was twice as high as in EC and FL. The amount of 3[H]-AA incorporated in the cellular lipid pool of MC, EC and FL depended on the concentration of AA in the incubation medium and the incubation time. In EC and FL incorporation of 3[H]-AA was highest in the cellular phospholipid pool (0.01 microM AA, 30 min incubation). With increased concentration of AA and longer incubation times, the cellular triacylglycerol pool became more important as site of 3[H]-AA incorporation. In MC, comparable amounts of 3[H]-AA were incorporated in the cellular triacylglycerol and phospholipid pools (0.01 and 1 microM AA). At higher AA concentrations (10 microM) the triacylglycerol pool was the preferred site of 3[H]-AA deposition. Autoradiographic analysis at the light microscopic level revealed that the extra-nuclear space was readily stained when the three cell types were incubated with 3[H]-AA. These findings indicate that all cellular lipid pools and membranes are most likely site of deposition of radiolabeled arachidonic acid.

Annexins in cardiac tissue: cellular localization and effect on phospholipase activity.

Stimulation of cardiac phospholipid metabolism has diverse biological effects, ranging from subtle changes in cellular function to severe cellular damage. Accordingly, knowledge of the factors governing the activity of cardiac phospholipases is of great biological importance. A possible role of annexins, intracellular proteins that bind to membranes in a calcium dependent manner, as modulators of phospholipase activity has been proposed. In this study we investigated the cell type specific distribution of Annexin V and VIII in the heart. Recombinant Annexin V was used to examine the effect of this type of Annexin on cardiac phospholipase activity. Western blot analysis shows that annexin V is abundantly present in the heart. Using isolated myocytes and cultured cardiac endothelial and fibroblast-like cells, it is demonstrated that the localization of Annexin V is confined to non-myocytes. No positive bands matching the Mw of recombinant Annexin VIII are found in any of the cell types examined. In vitro studies demonstrate that recombinant Annexin V potently inhibits the activity of cardiac membrane-bound phospholipases, acting on their natural surrounding substrate, in a calcium dependent manner. Interestingly, annexin V also inhibits triacylglycerol hydrolysis. In conclusion, the expression of annexins is cell-type specific and suggests a cell-type specific function of these proteins in the heart. The absence of Annexin V in cardiac myocytes dismisses involvement of this annexin in cardiomyocyte phospholipid metabolism. The presence of Annexin V in cardiac endothelial and fibroblasts suggests a regulating role in the phospholipid homeostasis of non-myocyte cell types in the heart.

Fatty acid accumulation during ischemia and reperfusion: effects of pyruvate and POCA, a carnitine palmitoyltransferase I inhibitor.

The present study was designed to evaluate the effects of POCA, a carnitine palmitoyltransferase I (CPT I) inhibitor, and pyruvate, a substrate inhibiting fatty acid (FA) oxidation, on post-ischemic cardiac FA accumulation on the one hand, and hemodynamic recovery and loss of cellular integrity on the other. To this end isolated, working rat hearts, receiving glucose (11 mM) as substrate, were subjected to 45 min of no-flow ischemia and 30 min of reperfusion. Hearts were perfused with or without POCA (10 microM) and/or pyruvate (5 mM). In the control group the FA content increased significantly during ischemia and remained elevated during reperfusion. Administration of POCA did not affect functional recovery and LDH release significantly, but resulted in about two-fold increased FA levels upon reperfusion as compared to glucose-perfused hearts. Pyruvate markedly improved functional recovery. Addition of this substrate did not affect lactate dehydrogenase (LDH) release, but enhanced FA accumulation during reperfusion. The combined administration of pyruvate and POCA nullified the positive effect of pyruvate on hemodynamic recovery, aggravated LDH release, and further enhanced the accumulation of FAs. The adenine nucleotide content of reperfused hearts was comparable for all groups investigated. In conclusion, during transient ischemia POCA and pyruvate markedly increased cardiac FA accumulation through inhibition of the oxidation of FAs released from endogenous lipid pools. No clear relation was found between the FA content of reperfused hearts and post-ischemic functional recovery.

Ischemia and reperfusion induced formation of eicosanoids in isolated rat hearts.

Isolated, ejecting rat hearts, perfused with Krebs-Henseleit buffer, were exposed to various periods of global ischemia. Arachidonic acid (AA) accumulated significantly in the ischemic heart when the duration of ischemia exceeded 45 min. During 30 min of reperfusion, tissue levels of AA raised steadily to values of 10.5, 17.7, and 63.1 nmol/g, after 30, 45, and 60 min of ischemia, respectively. During reperfusion, significant amounts of AA metabolite prostacyclin (determined as stable metabolite 6-ketoprostaglandin F1 alpha, by radioimmunoassay and high-performance liquid chromatography) were released after 30, 45, and 60 min of ischemia. Beside prostacyclin, only small amounts of thromboxane B2 could be found during reperfusion. In contrast to increasing amounts of AA in reperfused tissue, prostacyclin release was maximal during the first 5 min of reperfusion and declined rapidly thereafter. Relatively small proportions of the accumulated AA are converted into prostacyclin, i.e., less than 1%. When hearts were treated with mepacrine, AA accumulation was almost completely abolished during 60 min of ischemia. The cumulative release of prostacyclin was found to be reduced to 134 pmol/g during 30 min of subsequent reperfusion. A close, rectilinear correlation could be established between AA accumulation and cumulative prostacyclin release during reperfusion. It is likely, however, that the site of bulk AA accumulation and that of conversion of AA into eicosanoids does not coincide in the ischemic and reperfused heart because of the low conversion rates of AA into prostacyclin and the different time courses of AA accumulation and prostacyclin production after reinstallation of flow.

Effects of nicotinic acid and mepacrine on fatty acid accumulation and myocardial damage during ischemia and reperfusion.

To assess the nature of ischemia- and reperfusion-induced lipid changes and their consequences for myocardial function and integrity, Krebs-Henseleit perfused, isolated, working rat hearts were treated with nicotinic acid or mepacrine, putative inhibitors of triacylglycerol and phospholipid hydrolysis, respectively. In non-treated hearts 60 min ischemia resulted in a marked rise in myocardial fatty acid (FA) content. The FA content sharply increased further during 30 min reperfusion. Seven out of 16 (44%) hearts fibrillated continuously during reperfusion. Post-ischemic recovery of cardiac output (CO) of the non-fibrillating hearts amounted to 68 +/- 15% of the preischemic value. Nicotinic acid (10 microM) significantly reduced FA accumulation during ischemia (P less than 0.05), but not during reperfusion (0.05 less than P less than 0.10). Post-ischemic recovery of CO was improved (87 +/- 12%). This was neither associated with preservation of myocardial adenine nucleotide content, nor significant reduction of enzyme release. Mepacrine (1 microM) completely abolished reperfusion arrhythmias and improved recovery of CO (88 +/- 7% of pre-ischemic value). The reduction of FA content in ischemic and reperfused hearts did not reach the level of significance. Enzyme release was not attenuated. At 10 microM, mepacrine completely prevented accumulation of FAs during ischemia and reperfusion, abolished reperfusion-arrhythmias, and reduced enzyme release. No concomitant preservation of adenine nucleotides was observed. In conclusion, nicotinic acid and mepacrine are able to reduce ischemia- and reperfusion-induced changes in myocardial lipid metabolism. In addition, both drugs improve post-ischemic functional recovery. It remains to be established whether these effects are causally related.

Lactate-induced stimulation of myocardial triacylglycerol turnover.

The addition of lactate (5.6 mM) to a perfusion medium containing glucose (11 mM) stimulated the turnover of the cardiac triacylglycerol pool throughout the perfusion period as indicated by increased glycerol release in association with maintained levels of triacylglycerols. Attenuation of feedback inhibition of triacylglycerol lipase by fatty acids as a possible cause of the elevated triacylglycerol turnover rate should be ruled out, since tissue fatty acid levels were 3-times higher in glucose plus lactate perfused hearts than in hearts perfused with glucose as the sole substrate. The present findings are in favor of the notion that lactate enhances triacylglycerol turnover through increased glycerol 3-phosphate levels.

Degradation of adenine nucleotides in ischemic and reperfused rat heart.

Complete cessation of flow in isolated rat hearts for 90 min resulted in a gradual breakdown of ATP and concomitant accumulation of degradation products, such as adenosine, inosine (major break-down product), hypoxanthine, and, to a lesser extent, xanthine. After 45 min of ischemia, the content and relative composition of purines hardly changed, whereas the AMP content continued to rise. This finding points to constraints on AMP degradation and flux through the degradation pathway from adenosine to uric acid in the ischemic heart. In myocardial preparations, the cells of which were deliberately disrupted by freezing and thawing before anoxic incubation, AMP did not accumulate and was finally converted to hypoxanthine. These results indicate that compartmentalization of substrates and enzymes is responsible for the observed preferential accumulation of AMP and inosine in the ischemic heart. Inhibition of hypoxanthine degradation is explained by the absence of oxygen. Restoration of flow and oxygen supply abolished the inhibition of metabolic flux. Accumulated purines were released into the coronary effluent and, concomitantly, further metabolized. Comparison of tissue levels of hypoxanthine, xanthine, and uric acid before reperfusion and the amounts released during reperfusion indicates that in rat myocardium substantial amounts of potentially hazardous xanthine oxidase-derived reactive oxygen species are likely to be formed during the early reperfusion phase.

Degradation of phospholipids and triacylglycerol, and accumulation of fatty acids in anoxic myocardial tissue, disrupted by freeze-thawing.

The degradation of lipids by endogenous hydrolytic activity has been studied in rat cardiac tissue deliberately damaged by freezing and thawing prior to storage under anoxic conditions. Aliquots of the freeze-thawed material were kept at 37 degrees C under an atmosphere of N2 up to 120 minutes. Triacylglycerol was hydrolyzed at a rate of 0.14 mumol fatty acids per minute per gram dry weight of tissue. Hydrolysis of phosphatidylcholine (PC) and phosphatidylethanolamine (PE) was associated with proportional production of lyso PC and lyso PE, respectively. This finding indicates that the activity of lysophospholipase is negligible in autolyzing cardiac tissue. The rate of hydrolysis of PC and PE was found to be 0.10 and 0.06 mumol per minute per gram dry weight of tissue. The observation that lyso PC and lyso PE mainly contained saturated and mono-unsaturated fatty acids indicates that phospholipase A2 rather than A1 is active in autolyzing cardiac tissue. The accumulation of fatty acids corresponded with the loss of triacylglycerol and phospholipids from the tissue during 120 minutes of autolysis.

Lipid alterations in isolated, working rat hearts during ischemia and reperfusion: its relation to myocardial damage.

Disturbances in lipid metabolism may play an important role in the onset of irreversible myocardial damage. To investigate the effect of ischemia and reperfusion on lipid homeostasis and to delineate its possible consequences for myocardial damage, Krebs-Henseleit-perfused, working rat hearts were subjected to various periods of no-flow ischemia (10 to 90 minutes) with or without 30 minutes of reperfusion. During ischemia, the rise in nonesterified fatty acids (NEFAs) was preceded by the accumulation of substantial amounts of glycerol, indicating the presence of an active triacylglycerol-NEFA cycle. The subsequent rise in NEFAs (from 0.25 to 1.64 mumol/g dry residue wt after 90 minutes [means]) coincided with the reduction of ATP to values lower than 10 mumol/g dry wt and the rise of AMP, a potent inhibitor of acyl-coenzyme A synthetase, to values exceeding 2 mumol/g dry wt, making the latter compound a good candidate to hamper the turnover of endogenous lipids during prolonged ischemia. Reperfusion resulted in an additional rise in NEFAs (up to 4.1 mumol/g dry residue wt after 60 minutes of ischemia). Neither ischemia nor reperfusion resulted in significant decreases in the tissue content of triacylglycerols and the various phospholipids. During reperfusion recovery of stroke volume was still adequate at tissue NEFA levels thought to be incompatible with normal mitochondrial function. A positive correlation (r = 0.81) was found between NEFA content of reperfused hearts and cumulative release of lactate dehydrogenase during reperfusion. Accordingly it is concluded that 1) reperfusion results in additional changes in myocardial lipid homeostasis, 2) the accumulating NEFAs are compartmentalized, possibly at the cellular level, and 3) the accumulation of NEFAs is a sensitive marker for myocardial cell damage.