Cardiac Ischemia Activates Calcium-independent Phospholipase A2{beta}, Precipitating Ventricular Tachyarrhythmias in Transgenic Mice

RESCUE OF THE LETHAL ELECTROPHYSIOLOGIC PHENOTYPE BY MECHANISM-BASED INHIBITION*

David J. Mancuso {ddagger} §, Dana R. Abendschein §, Christopher M. Jenkins {ddagger} §, Xianlin Han {ddagger} §, Jeffrey E. Saffitz § ¶, Richard B. Schuessler || and Richard W. Gross {ddagger} § ** {ddagger}{ddagger} §§

From the {ddagger}Division of Bioorganic Chemistry and Molecular Pharmacology and the Departments of §Medicine, **Chemistry, {ddagger}{ddagger}Molecular Biology and Pharmacology, ||Surgery, and Pathology, Washington University School of Medicine, St. Louis, Missouri 63110

Received for publication, January 23, 2003 , and in revised form, March 20, 2003.


    ABSTRACT
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Murine myocardium contains diminutive amounts of calcium-independent phospholipase A2 (iPLA2) activity (<5% that of human heart), and malignant ventricular tachyarrhythmias are infrequent during acute murine myocardial ischemia. Accordingly we considered the possibility that the mouse was a species-specific knockdown of the human pathologic phenotype of ischemiainduced lethal ventricular tachyarrhythmias. Transgenic mice were generated expressing amounts of iPLA2{beta} activity comparable to that present in human myocardium. Coronary artery occlusion in Langendorff perfused hearts from transgenic mice resulted in a 22-fold increase in fatty acids released into the venous eluent (29.4 nmol/ml in transgenic versus 1.35 nmol/ml of eluent in wild-type mice), a 4-fold increase in lysophosphatidylcholine mass in ischemic zones (4.9 nmol/mg in transgenic versus 1.1 nmol/mg of protein in wild-type mice), and malignant ventricular tachyarrhythmias within minutes of ischemia. Neither normally perfused transgenic nor ischemic wild-type hearts demonstrated these alterations. Pretreatment of Langendorff perfused transgenic hearts with the iPLA2 mechanism-based inhibitor (E)-6-(bromomethylene)-3-(1-naphthalenyl)-2H-tetrahydropyran-2-one (BEL) just minutes prior to induction of ischemia completely ablated fatty acid release and lysolipid accumulation and rescued transgenic hearts from malignant ventricular tachyarrhythmias. Collectively these results demonstrate that ischemia activates iPLA2{beta} in intact myocardium and that iPLA2{beta}-mediated hydrolysis of membrane phospholipids can induce lethal malignant ventricular tachyarrhythmias during acute cardiac ischemia.


    INTRODUCTION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Electrophysiologic dysfunction is the major cause of death during myocardial infarction in humans (1). Years ago we suggested that activation of myocardial phospholipases during acute cardiac ischemia resulted in the generation of amphiphilic metabolites that alter ion channel function, thereby precipitating lethal ventricular dysrhythmias (210). Since myocytic electrophysiologic function is influenced by the physiochemical properties of the lipids surrounding ion channels (1113), accelerated hydrolysis of sarcolemmal phospholipid constituents during acute ischemia could potentially provide a foundation for understanding the biochemical basis of ischemia-induced arrhythmias. However, a cause and effect relationship between ischemia-induced phospholipolysis and malignant ventricular arrhythmias has not previously been established. Moreover, myocardium contains at least three distinct intracellular phospholipase A2 (PLA2)1 activities encoded by discrete genes (iPLA2{beta}, iPLA2{gamma}, and cPLA2{gamma}) (1416), and the molecular identity of the phospholipase A2 activated during cardiac ischemia is unknown. Finally, although each of these enzymes has been cloned, expressed, purified from recombinant systems, and subjected to detailed in vitro kinetic analyses, definitive proof of the ability of any of these discrete covalent entities (in the cPLA2 or iPLA2 families) to hydrolyze phospholipids in intact organs has not been directly demonstrated.

Calcium-independent phospholipase A2 activity was initially discovered in the cytosolic and membrane fractions of canine myocardium and identified as a novel phospholipase A2 activity by its ability to hydrolyze fatty acids from the sn-2 position of vinyl ether or diacyl phospholipids in the presence of EGTA (5). These studies unambiguously demonstrated that this activity was a bona fide phospholipase A2 since release of the sn-2 acyl chain from ether lipids could not result from sequential phospholipase A1 followed by lysophospholipase activities. Purification of canine myocardial cytosolic iPLA2 resulted in the isolation of a high specific activity 40-kDa polypeptide (6) whose identity was substantiated by its robust radiolabeling with the mechanism-based inhibitor (E)-6-(bromomethylene)tetrahydro-3-(1-[4-3H]naphthalenyl)-2H-pyran-2-one (17). Likewise purification of iPLA2 from human myocardium also identified a high specific activity 40-kDa isoform (as in canine myocardium) and a larger 85-kDa polypeptide of lower specific activity (18). Subsequent work has demonstrated that the 40-kDa polypeptide was a proteolytic fragment of a larger gene that has now been cloned and had its 85-kDa protein product expressed and purified to homogeneity by tandem affinity chromatography (14, 19). Multiple groups have now observed the presence of the 40-kDa proteolytically processed form of iPLA2{beta} in recombinant and naturally occurring subcellular fractions from different cell types (e.g. see Refs. 2022). In continuing studies from our laboratory, we have demonstrated that iPLA2{beta} activity is modulated by ATP (9) and calcium-activated calmodulin (23). Moreover iPLA2{beta} is activated by internal calcium pool depletion mediated by thapsigargin or other sarco(endo)plasmic reticulum Ca2+-ATPase inhibitors (24). Since alterations in energy metabolism and calcium ion homeostasis have both been implicated as important mediators of ischemic dysfunction, we hypothesized that iPLA2{beta} was the enzymic mediator of accelerated lipid metabolism, altered membrane molecular dynamics, increased lipid second messenger generation, and electrophysiologic dysfunction in ischemic zones. Detailed studies have identified the ATP binding site (residues 431–450) and the calmodulin binding site (residues 690–752) in iPLA2{beta} (25). Recently we cloned and expressed a related peptide possessing both the ATP and lipase consensus sequence sites termed iPLA2{gamma} (GenBankTM accession number AF263613 [GenBank] ) that contains a peroxisomal localization site and is not modulated by calmodulin (16).

Murine cardiac ischemia is accompanied by increases in anaerobic glycolysis, lactate production, alterations in high energy phosphate metabolism, dysfunctional calcium ion homeostasis, and contractile dysfunction, each of which are virtually indistinguishable from those manifest in human and other animal models of cardiac ischemia (26, 27). These changes in mouse, as in human cardiac ischemia, are each reversible if reperfusion occurs within 15 min of the ischemic episode (28, 29). After 25–30 min of ischemia, these biochemical alterations become irreversible, leading to myocytic cellular necrosis, cell death, and permanent hemodynamic compromise. This constellation of findings is present in virtually every animal model of cardiac ischemia studied including humans (3032). However, murine myocardial ischemia differs from ischemia in humans (and other animal models) by virtue of the fact that ventricular arrhythmias are uncommon in ischemic mouse hearts during the first 15 min of ischemia (i.e. prior to cellular necrotic changes) (33, 34). Due to its relative ease of genetic manipulation, the mouse has become the prototypic model for validation of hypotheses implicating specific proteins in whole organ pathophysiologic processes. During the course of our studies, we demonstrated that murine myocardium possesses extremely low levels of iPLA2{beta} activity, and others have reported that malignant ventricular tachyarrhythmias are infrequent during murine acute cardiac ischemia (33, 34). To determine whether the diminutive amounts of cardiac phospholipase A2 activity in murine myocardium and the paucity of ischemiainduced malignant tachyarrhythmias in the mouse were serendipitous findings or represented a natural species-specific knockdown of an important human pathophysiologic phenotype, we expressed iPLA2{beta} in transgenic mice in a cardiac myocyte-specific manner by exploiting the selectivity of the {alpha} myosin heavy chain ({alpha}MHC) promoter. We utilized Langendorff perfused heart preparations of wild-type and transgenic mice to facilitate the detailed and coordinated analyses of alterations in iPLA2{beta}-mediated phospholipolysis and ventricular arrhythmias after the induction of cardiac ischemia. We now report that myocardial ischemia activates iPLA2{beta} in intact myocardium, that iPLA2{beta} activation is sufficient to induce malignant ventricular arrhythmias, and that both the lethal lipid and electrophysiologic ischemic phenotypes can be concomitantly rescued by mechanism-based inhibition of iPLA2{beta} enzymic activity.


    EXPERIMENTAL PROCEDURES
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Materials—ECL reagents were purchased from Amersham Biosciences. A DNA thermocycler and PCR reagents were purchased from PerkinElmer Life Sciences. L-{alpha}-1-Palmitoyl-2-[1-14C]arachidonyl phosphatidylcholine was purchased from PerkinElmer Life Sciences. BEL was obtained from Calbiochem. Most other reagents were obtained from Sigma.

Generation of Transgenic Mice Overexpressing iPLA2{beta} in a Cardiac Myocyte-specific Manner—Cardiac myocyte-specific expression of iPLA2{beta} in transgenic mice was accomplished by cloning the full-length 2.4-kb coding region of the wild-type Chinese hamster iPLA2{beta} (from iPLA2{beta}-pFAST (19)) into the SalI site of the {alpha}MHC vector downstream from the {alpha}MHC promoter (35). Transgenic founders were generated by microinjection of a NotI-linearized fragment containing the {alpha}MHC promoter-iPLA2{beta} DNA sequence directly into the pronuclei of mouse (B6CBAF1/J) zygotes, resulting in integration of the transgene into the mouse germ line. Two founders, identified by PCR analysis of mouse tail DNA, were mated with C57Bl/J6 mice (Jackson Laboratories, Bar Harbor, ME) to establish transgenic lines. Second and third generation heterozygous mice, typically 3–4 months of age, were used for all studies.

Homogenization and Western Blot Analysis of Control and Transgenic Mouse Hearts—For preparation of cytosolic and membrane fractions, samples of tissue were homogenized in 25 mM imidazole, pH 8.0, containing 1 mM EGTA and 0.25 M sucrose using a Polytron tissue homogenizer and centrifuged at 100,000 x g for 1 h to separate crude membrane and cytosolic (supernatant) fractions. The membrane fraction was resuspended in a volume of homogenization buffer equal to the cytosolic fraction. Proteins were separated by SDS-PAGE (36) and transferred to polyvinylidene difluoride membranes as described previously (25). Cytosolic and resuspended membrane fractions were probed with antibodies directed against iPLA2{beta} peptide corresponding to residues 277–295 (CSQIHSKDPRYGASPLHWAK) (25) in conjunction with a protein A-horseradish peroxidase conjugate for visualization by enhanced chemiluminescence. Recombinant iPLA2{beta} prepared as described previously was used as a standard (19).

Extraction and Electrospray Ionization Mass Spectrometry of Lipids from Wild-type and Transgenic Mouse Myocardium—Lipids were extracted from mouse myocardium (~50 mg) by a modified Bligh and Dyer technique. Mass spectrometry (ESI/MS) analyses were performed using a Finnigan TSQ-7000 spectrometer as described previously (3739). For analyses of choline and ethanolamine glycerophospholipids as well as free fatty acids, LiOH in methanol (50 nmol/mg of protein) was added to the diluted tissue extracts. Membrane choline glycerophospholipids (including lysophosphatidylcholines) and sphingomyelins were directly quantitated as their lithium adducts by reference to internal standard (i.e. lithiated 14:1-14:1 glycerophosphocholine) after correction for 13C isotope effects in the positive ion mode (3739). In a similar manner, ethanolamine glycerophospholipids were directly quantitated in the negative ion mode from membrane extracts rendered mildly basic with LiOH. For analyses of plasmalogen molecular species, lipid extracts were treated with acidic vapors prior to mass spectrometric analyses for differentiation of alkenyl-acyl from alkyl-acyl phospholipid molecular species. Similarly free fatty acids in lipid extracts rendered mildly basic by LiOH were directly quantitated in comparison to an internal standard (i.e. arachidic (C20:0) acid) after correction for 13C isotope effects in the negative ion mode. For anionic phospholipid analysis, diluted chloroform extracts of membrane samples were analyzed in the negative ion mode, and quantitation was made by comparisons to internal standard (i.e. 14:1-14:1 glycerophosphocholine) ion peak intensity. For analyses of individual molecular species, assignment of each ion peak was substantiated by tandem mass spectroscopic analyses in the molecular ion, neutral loss, or product ion scanning modes. Quantification of ion peaks corresponding to multiple individual isobaric molecular ions was substantiated using product ion ESI/MS/MS analyses (3739).

Electrophysiologic Studies with Isolated Langendorff Perfused Mouse Hearts—Ventricular tachyarrhythmias induced by acute ischemia were characterized using an isolated Langendorff perfused heart preparation as described previously by Lerner et al. (32). Frequencies of spontaneous arrhythmias (premature ventricular contractions (PVCs) and episodes of malignant ventricular tachyarrhythmias (VT)) were counted for 30 min after coronary ligation and tabulated as PVC frequency per 5-min intervals. A run of ventricular tachycardia was defined as 10 or more beats with a cycle length <100 ms. After 30 min, hearts were perfused through the aortic catheter with 1% Evans blue dye to delineate the ischemic zone for subsequent tissue analyses. To determine the effects of BEL on induction of arrhythmias after ischemia, hearts were perfused with buffer containing 10 µM BEL beginning 5 min before coronary artery ligation and during the ischemic interval. All studies were randomized and blinded.

Assay of Calcium-independent Phospholipase A2 Activity—Calcium-independent phospholipase A2 activity was measured by quantitating the release of radiolabeled fatty acid from L-{alpha}-1-palmitoyl-2-[1-14C]arachidonyl phosphatidylcholine in the presence of cytosolic or membrane fractions as described previously (19).

Statistical Analyses—One-way repeated measures ANOVA was used to compare the frequencies of spontaneous PVCs in wild-type control and transgenic iPLA2{beta} (TGiPLA2{beta}) hearts over consecutive 5-min intervals during 30 min of ischemia with or without BEL pretreatment as indicated. Individual comparisons between wild-type control and TGiPLA2{beta} groups at each time interval studied were made with a twotailed Student's t test. The total number of episodes of VT in wild-type and TGiPLA2{beta} transgenic hearts during 30 min of ischemia in the presence or absence of BEL pretreatment were compared by ANOVA. A value of p < 0.05 was considered significant.


    RESULTS
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Transgenic mice expressing iPLA2{beta} in a cardiac myocyte-specific fashion were generated by exploiting the specificity inherent in the {alpha}MHC promoter. Tissue samples from the major organs of wild-type and TGiPLA2{beta} mice revealed the presence of an intense band corresponding to iPLA2{beta} at the expected molecular mass (85 kDa) in transgenic hearts that was not visible in wild-type heart tissue (Fig. 1A). No expression was detected in brain or liver, while a faint band corresponding to iPLA2{beta} was detected in the kidneys of transgenic mice. Both cytosolic and crude membrane fractions from myocardium of TGiPLA2{beta} mice displayed robust iPLA2{beta} catalytic activity, while cardiac iPLA2{beta} activity was diminutive in wild-type mice (Fig. 1B). It should be noted that the amount of iPLA2{beta} activity present in transgenic mice is comparable to that naturally present in rabbit (2, 40), canine (4, 8), and human myocardium (10, 41). No differences in cardiac function were detected by echocardiographic analysis of 4-month-old animals nor were there any differences in the body weights of littermates, heart weights, or gross appearance of hearts present. Electron microscopic examination of TGiPLA2{beta} hearts demonstrated normal cellular architecture except for the occasional areas in some cells of highly organized electron dense crystalline arrays that are currently being purified and will be reported on in due course. Phospholipid molecular species analysis by ESI/MS demonstrated modest but statistically significant decreases in some species of choline and ethanolamine glycerophospholipids (Fig. 2, A and B). However, despite the large increase in iPLA2{beta} activity in comparison to wild-type (WT) mice, no substantial differences in the relative amounts of each molecular species were present. Thus, there was a modest decrease in phospholipids without any remodeling present (i.e. iPLA2{beta} does not facilitate membrane remodeling). No significant alterations in cardiac anionic phospholipids or in sphingomyelin mass and molecular species content between WT and TGiPLA2{beta} hearts were present.



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FIG. 1.
iPLA2{beta} expression in wild-type and transgenic mice. A, Western analysis of iPLA2{beta} expression in cytosol from selected tissues including brain, heart, liver, and kidney from WT and transgenic (TG) mice (25 µg of protein/lane). Purified recombinant iPLA2{beta} was used as standard. B, iPLA2{beta} activity present in the cytosolic fractions of brain, heart, liver, and kidney of wild-type and TGiPLA2{beta} mice. Phospholipase A2 activity assays were performed by measuring arachidonic acid (AA) released (nmol)/mg of protein/min as described under "Experimental Procedures." Error bars indicate ±S.E. for three separate experiments. n = 3.

 


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FIG. 2.
Electrospray ionization mass spectroscopy of phospholipids in wild-type and transgenic myocardium. A, ethanolamine glycerophospholipid (PE) molecular species in WT (light bars) versus TGiPLA2{beta} (dark bars) myocardium. Individual ethanolamine glycerophospholipid molecular species quantified include: 1, P16:1-20:4; 2, P16:0-22:6; 3, P18:1-20:4; 4, D16:0-22.6; 5, D16:0-22.4; 6, P18:1-22:6; 7, P18:0-22:6; 8, P18:1-22:4; 9, P18:0-22:4; 10, D18:1-22:6; 11, D18:0-22:6 where D and P denote diacyl and plasmenyl subclasses, respectively. *, p < 0.01; **, p < 0.001 (n = 3). B, phosphatidylcholine (PC) molecular species in WT (light bars) versus TGiPLA2{beta} (dark bars) hearts. Individual molecular species quantified include: 1, 16:0-16:0; 2, 16:0-18:2; 3, 16:0-18:1; 4, 16:0-20:4; 5, 18:1-18:1; 6, 18:0-18:1; 7, 16:0-22:6; 8, 16:1-22:4; 9, 18:0-20:4; 10, 18:0-22:6; 11, 18:1-22:4. *, p < 0.01; **, p < 0.001 (n = 3). In each case, other molecular species representing <2% of the total pools were also identified without demonstrable differences between control and transgenic mice.

 

To determine whether myocardial ischemia activates iPLA2{beta}, resulting in iPLA2{beta}-catalyzed hydrolysis of lipids in intact myocardium, a Langendorff perfused heart preparation was used. Samples of normally perfused and ischemic tissue from control and TGiPLA2{beta} hearts were analyzed for fatty acid and lysolipid mass by ESI/MS. Similarly the release of fatty acids into the effluent during control and ischemic conditions was quantified. This strategy provides clear data on the amount of PLA2 activity manifest in the ischemic milieu in intact myocardium and avoids potential artifacts resulting from intrapreparative alterations in the enzyme (covalent or conformational) or the loss of effects of critical regulators of iPLA2 activity (e.g. ATP and calmodulin) during the homogenization process. After 15 min of coronary occlusion, release of fatty acids into effluents from TGiPLA2{beta} perfused hearts increased 22-fold compared with WT controls. Similarly a 4-fold increase in fatty acid and lysophosphatidylcholine accumulation in the ischemic zone of hearts was present in TGiPLA2{beta} mice but not in WT mice (Fig. 3). Moreover the release of fatty acids into the venous eluent and the accumulation of lysolipids and fatty acids in ischemic zones of hearts from transgenic mice were nearly completely ablated by pretreatment of Langendorff perfused hearts with the iPLA2{beta} mechanism-based inhibitor BEL (Fig. 3). We specifically point out that murine ischemia in wild-type hearts was remarkable for the near absence of fatty acid release into the eluent and the absence of lysophosphatidylcholine and fatty acid accumulation in ischemic zones, which contrasts dramatically with every other model of cardiac ischemia previously studied (including humans).



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FIG. 3.
Electrospray ionization mass spectrometric determination of fatty acid release and lysophosphatidylcholine accumulation in WT and TGiPLA2{beta} Langendorff perfused hearts. A, nonesterified fatty acid (NEFA) release obtained from effluent from control or ischemic Langendorff hearts at 15 min. *, p < 0.0001. B, nonesterified fatty acid mass in ischemic heart tissue from WT and TGiPLA2{beta} hearts. *, p < 0.01. C, lysophosphatidylcholine (LPC) mass in ischemic tissue from WT and TGiPLA2{beta} hearts. *, p < 0.0001. Release of nonesterified fatty acid into the effluents (A) and accumulation of nonesterified fatty acid (B) and lysophosphatidylcholine (LPC) (C) in ischemic tissue from Langendorff perfused hearts (WT (light bars) and TGiPLA2{beta} (dark bars)) were measured in the absence or presence of LAD coronary artery occlusion (ischemia) in the absence (–) or presence (+) of BEL pretreatment as indicated.

 

To determine the role of iPLA2{beta} in arrhythmogenesis during acute cardiac ischemia, hearts from WT and TGiPLA2{beta} mice were examined for PVCs and malignant ventricular arrhythmias after coronary ischemia in a Langendorff perfused heart preparation (32). Virtually no PVCs were observed in hearts from TGiPLA2{beta} mice under normal flow conditions. However, ligation of the left anterior descending coronary artery in hearts from TGiPLA2{beta} mice resulted in an increased frequency of PVCs and couplets within minutes of cardiac ischemia that was accompanied by malignant VT. The frequency of spontaneous PVCs was higher in hearts expressing iPLA2{beta} compared with controls at each 5-min time interval examined during the first 20 min of ischemia (p = 0.0003 versus WT by repeated measures ANOVA) (Fig. 4A). The greatest increases in PVC frequency in TGiPLA2{beta} hearts occurred in the 10–15- and 15–20-min intervals after coronary ligation. The PVC frequencies in these intervals were an average of 5.5-fold higher than that of the wild-type control hearts. Multiple episodes of nonsustained VT occurred in TGiPLA2{beta} hearts (VT occurred in 9 of 24 hearts) compared with a single episode in one WT heart (1 of 19 hearts) (p = 0.002 by ANOVA) (Fig. 4C). All episodes of VT terminated spontaneously.



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FIG. 4.
PVCs and VT after coronary ligation in the presence and absence of BEL in wild-type and iPLA2{beta} transgenic Langendorff perfused mouse hearts. Data are presented as the mean ± S.D. A, frequency of PVCs in wild-type control mouse hearts (open bars, n = 19) and in TGiPLA2{beta} transgenic mouse hearts (closed bars, n = 24) in the absence of BEL pretreatment (–BEL). Total PVCs were recorded in 5-min intervals (0–5, 5–10, 10–15, 15–20, 20–25, and 25–30 min) after ligation of the LAD coronary artery in TGiPLA2{beta} and wild-type control Langendorff hearts. The mean PVC frequency per interval (PVC frequency/5-min interval) was then plotted versus time interval after coronary ligation. Repeated measures ANOVA showed a significant difference between the PVC frequencies for wild-type controls and TGiPLA2{beta} mice (p = 0.0003). B, the effect of BEL pretreatment (+BEL) on PVC frequency measured in 5-min intervals after coronary ligation. Repeated measures ANOVA showed a significant decrease in PVC frequency/5-min interval for BEL-treated TGiPLA2{beta} hearts (p = 0.002 comparing TGiPLA2{beta} with versus without BEL pretreatment, n = 10). Similarly BEL pretreatment reduced PVC frequency in WT hearts (p = 0.03 comparing WT with and without BEL pretreatment, n = 8). C, frequency histogram showing total episodes of VT in TGiPLA2{beta} transgenic hearts (closed bars, n = 24) versus wild-type control hearts (open bars, n = 19) with (+) and without (–) BEL pretreatment. BEL pretreatment resulted in a significant reduction of VT episodes in transgenic hearts as determined by ANOVA (p = 0.002).

 

To determine whether specific pharmacologic inhibition of the iPLA2{beta} transgene perfused hearts could rescue perfused hearts from malignant ventricular arrhythmias, the mechanism-based inhibitor BEL (42) was used. Perfusion of hearts with buffer containing BEL (10 µM) beginning 5 min prior to and continuously during ischemia inhibited the frequency of PVCs in TGiPLA2{beta} hearts (p = 0.002 by repeated measures ANOVA compared with hearts without BEL pretreatment) and in WT control hearts (p = 0.03 by repeated measures ANOVA compared with hearts without BEL pretreatment) (Fig. 4B). Moreover BEL pretreatment completely abolished VT in TGiPLA2{beta} Langendorff perfused hearts (0 of 10 mouse hearts) (Fig. 4C, p = 0.002 by ANOVA comparing TGiPLA2{beta} hearts with and without BEL pretreatment).

The concurrent activation of iPLA2{beta} during ischemia in conjunction with the generation of malignant ventricular arrhythmias and their rescue by inhibition of the expressed iPLA2{beta} transgene formally fulfills traditional criteria for proof of a cause and effect relationship between two phenomena (i.e. malignant arrhythmias are rare when diminutive amounts of iPLA2{beta} activity are present (WT mice), malignant arrhythmias are manifest during activation of the expressed iPLA2{beta} transgene by ischemia, and arrhythmias are ablated by mechanism-based inhibition of the expressed iPLA2{beta} enzymic activity).


    DISCUSSION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
The results of the present study identify the rapid and dynamic activation of iPLA2{beta} activity in response to ischemia in intact myocardium and its role in ischemic electrophysiologic dysfunction. Since the initial discovery of intracellular calcium-independent phospholipases A2, a substantial controversy has evolved regarding their role as dynamic enzymes responding to pathophysiologic perturbations or whether iPLA2 activities represented static "housekeeping" enzymes responsible for phospholipid remodeling. Prior results utilizing a variety of cell culture systems, tissue homogenates, purified enzymes, and pharmacologic inhibitors have all strongly suggested an important role for iPLA2 in mediating dynamic cellular responses to a variety of physiologic or pathophysiologic stimuli. For example, prior work has demonstrated that iPLA2 1) associates with and is modulated by ATP and calmodulin (23, 41), 2) mediates ligand-induced arachidonic acid release in many cell types (4347), 3) is a sensor of metabolic alterations modulating insulin release (40, 41) and mitochondrial function (22, 48), and 4) modulates ion channel kinetics (13, 49). The results of the present study provide unambiguous evidence for the dynamic and rapid response of iPLA2{beta} to the pathologic perturbation of ischemia in intact myocardium and underscore its role as a biochemical mediator of arrhythmogenesis in ischemic myocardium.

Death from ventricular tachyarrhythmias during acute myocardial ischemia is the major cause of mortality from atherosclerotic heart disease. Comprehensive epidemiologic and electrophysiologic studies have documented that the majority of human victims of acute myocardial ischemia die from ventricular tachyarrhythmias. Due to the relative ease of genetic manipulation of mouse embryos, the mouse has become the standard model for examining the role of specific proteins in prominent human diseases. For example, important insights into the mechanisms underlying atherosclerosis, diabetes, and cardiac diseases have been gleaned from murine models, although unquestionably substantial differences in mouse and human diseases are present. In humans and in most animal models of ischemia, ventricular arrhythmias become manifest after 2–15 min of ischemia and subside as continued ischemia (>25–30 min) results in cell death (1, 32). However, during acute murine ischemia, spontaneous VT occur infrequently (31, 32) in contrast to the 35–60% incidence of malignant ventricular tachyarrhythmias present in most other species after LAD coronary artery occlusion (e.g. rabbit, rat, pig, dog, and human) (1, 24, 3133, 50, 51).

In all cases of which we are aware, acute ischemia-induced arrhythmogenesis is accompanied by phospholipolysis (as assessed by release of fatty acids and accumulation of lysolipids). The present results unequivocally demonstrate that murine ischemia in wild-type mice is not accompanied by fatty acid release as is present in every other animal model of ischemia previously studied of which we are aware. We have exploited the natural species-specific knockdown of iPLA2 in the mouse (which does not possess substantial iPLA2 activity and does not release fatty acids or accumulate lysolipids during ischemia) to recapitulate complex ventricular tachyarrhythmias during murine myocardial ischemia by expressing amounts of iPLA2 activity in transgenic mice that are comparable to those present in wild-type rat, rabbit, dog, and human myocardium (6, 8, 10, 40). The fact that the observed arrhythmias were due to the catalytic competency of the expressed iPLA2{beta} transgene was substantiated by the rescue of ischemia-induced ventricular tachyarrhythmias in TGiPLA2{beta} ischemic hearts through mechanism-based inhibition by BEL. Moreover rescue of malignant ventricular tachyarrhythmias in transgenic animals by BEL pretreatment just minutes prior to ischemia demonstrates that no preexisting abnormality was present in transgenic hearts predisposing them to arrhythmogenesis that was not immediately reversible by BEL. For example, the reversibility by BEL rules out developmental alterations in the conduction system of transgenic mice predisposing them to arrhythmias or anatomical developmental abnormalities as a cause of arrhythmias in this study. The demonstration that amounts of fatty acids released in TGiPLA2{beta} hearts during ischemia are similar to amounts present in venous eluents in other animal and human paradigms of cardiac ischemia suggests that the amount of phospholipolysis occurring in this transgenic model has physiologic relevance.

Since cardiac electrophysiologic characteristics are dependent on the lipid constituents surrounding ion channels, it seems likely that ischemia induces activation of iPLA2{beta} in a way in that it can effectively access and hydrolyze sarcolemmal phospholipids. Indeed, in a cell culture model of cardiac ischemia, we have demonstrated the rapid and selective hydrolysis of sarcolemmal membrane lipids in response to metabolic deprivation by quantitative electron microscopic autoradiography (52). Many factors contribute to arrhythmogenesis in humans including the heterogeneity of ischemic damage, the metabolic history of the compromised myocyte, and the magnitude and duration of the ischemic insult. The present results show that in early ischemic injury prior to cell death (5–15 min) accelerated phospholipolysis can precipitate electrophysiologic dysfunction, while at later time points after irreversible injury and cell death (25–30 min), the frequency of arrhythmias in dying tissue is similar to that manifest in both WT and transgenic animals.

Although it was not known when initially discovered in the 1980s (210), this system is among the most ancestral of signaling systems, being extensively utilized in plants and insects. For example, a calcium-independent phospholipase A2 is the enzymic mediator of the "elicitor"-evoked acidification of plant cytosol that is utilized to protect plants from invasion by bacteria or fungi (53). The elicitor system in plants utilizes RW and RG receptor-mediated activation of a calcium-independent phospholipase A2 in the plasma membrane leading to lysophosphatidylcholine generation and the subsequent activation of the vacuolar proton transporter resulting in cytosolic acidification (53). Similarly, in Periplanta americana, exposure to hypertrehalose factor II, or alternatively depletion of internal calcium stores by thapsigargin, results in iPLA2 activation and ryanodine receptor-mediated increases in calcium ion flux (54). Indeed we have demonstrated the calcium-dependent calmodulin-regulated modulation of myocardial iPLA2 activity (23) and have identified IQ and 1-9-14 motifs near the C terminus that mediate the interaction between iPLA2{beta} and calmodulin (25). Recent studies by Bolotina and co-workers (49) implicate iPLA2 as the enzyme system mediating altered ISOC and ICRAC currents in a variety of different cell types. Collectively these studies identify an ancestral signaling pathway hundreds of millions of years old that, in ischemic myocardium, leads to electrical instability in ischemic zones in Homo sapiens. The precise electrical and ionic mechanisms that result from dysfunctional iPLA2 activation during ischemia are complex with contributions from multiple signaling cascades likely initiated by lysolipids and fatty acids generated by iPLA2 catalysis. Alterations in membrane molecular dynamics and aliphatic chain and polar head group conformational space likely contribute to the observed effects. Whatever the precise biochemical mechanisms underlying iPLA2-mediated electrophysiologic dysfunction in ischemic zones, these results unambiguously demonstrate that iPLA2{beta} is activated in ischemic zones and hydrolyzes phospholipid substrate (accumulation of lysophosphatidylcholine) in ischemic zones and that iPLA2 activation is sufficient to induce electrophysiologic dysfunction during cardiac ischemia. We specifically point out that these experiments do not mean that other factors do not contribute to ischemiainduced arrhythmogenesis but rather that ischemia-induced activation of iPLA2{beta}-mediated hydrolysis is sufficient to induce ventricular tachyarrhythmias with a time course, pattern, and frequency in the ischemic mouse heart that is strikingly similar to that present in humans (1, 32). These studies, in conjunction with the high iPLA2{beta} activity present in human myocardium (10, 41), strongly support the notion that iPLA2{beta}-mediated hydrolysis is a prominent, and perhaps a major factor, in ventricular electrical dysfunction and sudden death during human myocardial ischemia.


    FOOTNOTES
 
* This research was supported jointly by National Institutes of Health Grants 2PO1HL57278-06A1 and 2RO1HL41250-10. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. Back

§§ To whom correspondence should be addressed: Division of Bioorganic Chemistry and Molecular Pharmacology, Dept. of Medicine, Washington University School of Medicine, 660 South Euclid Ave., Campus Box 8020, St. Louis, MO 63110. Tel.: 314-362-2690; Fax: 314-362-1402.

1 The abbreviations used are: PLA2, phospholipase A2; iPLA2, calcium-independent phospholipase A2; BEL, (E)-6-(bromomethylene)-3-(1-naphthalenyl)-2H-tetrahydropyran-2-one; ESI/MS, electrospray ionization mass spectrometry; MS/MS, tandem MS; PVC, premature ventricular contraction; VT, ventricular tachyarrhythmias; LAD, left anterior descending; TGiPLA2{beta}, transgenic iPLA2{beta}; {alpha}MHC, {alpha} myosin heavy chain; ANOVA, analysis of variance; cPLA2, cytosolic phospholipase A2; WT, wild-type. Back



    REFERENCES
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 

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