Persistence of gap junction communication during myocardial ischemia

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Persistence of gap junction communication during myocardial ischemia

Marisol Ruiz-Meana¹, David Garcia-Dorado¹, Sinead Lane², Pilar Pina¹, Javier Inserte¹, Maribel Mirabet¹, and Jordi Soler-Soler¹

¹ Department of Cardiology, Hospital General Vall d'Hebron, Barcelona 08035, Spain; and ² Department of Pharmacology, University College of Cork, Ireland

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

During myocardial ischemia, severe ATP depletion induces rigor contracture followed by intracellular Ca²⁺ concentration ([Ca²⁺]_i) rise and progressive impairment of gap junction (GJ)-mediatedelectrical coupling. Our objective was to investigate whetherchemical coupling through GJ allows propagation of rigor in cardiomyocytesand whether it persists after rigor development. In end-to-endconnected adult rat cardiomyocytes submitted to simulated ischemiathe interval between rigor onset was 3.7 ± 0.7 s, and subsequent[Ca²⁺]_i rise was virtually identical in both cells, whereas in nonconnectedcell pairs the interval was 71 ± 12 s and the rate of [Ca²⁺]_i rise was highly variable. The GJ blocker 18 $alpha$ -glycyrrhetinicacid increased the interval between rigor onset and the differencesin [Ca²⁺]_i between connected cells. Transfer of Lucifer yellow demonstratedGJ permeability 10 min after rigor onset in connected cell pairs,and 30 min after rigor onset in isolated rat hearts submittedto nonflow ischemia but was abolished after 2 h of ischemia. GJ-mediatedcommunication allows propagation of rigor in ischemic myocytesand persists after rigor development despite acidosis and increased[Ca²⁺]_i.

propagation; rigor contracture; calcium

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

CARDIAC MYOCYTES are tightly interconnected by means of highly specialized regions of the plasma membrane known as gap junctions(GJ), which are composed of multiple intercellular channels. Thesechannels are the physical mediators of electrical coupling inthe heart and allow myocardium to behave as a functional syncytium.In ventricular myocytes, GJ channels are mainly formed by connexin43(Cx43) (11, 42). There is strong evidence that impaired electricalcoupling due to alterations in the number, spatial distribution,or function of myocardial GJ has a causative role in the genesisof arrhythmias associated with different conditions, includingacute ischemia and chronic myocardial infarction (6, 22,35). However, although GJ allow the exchange of small moleculesand ions (20, 26), little is known about the consequencesof metabolic coupling between adult cardiac myocytes under normalor pathologic conditions such as myocardial ischemia-reperfusion.There is increasing evidence that chemical communication throughGJ may allow spread of various types of cell injury in differenttissues (7, 32, 33), and it has been recently proposedthat it may allow propagation of cell injury during myocardialreperfusion (16).

It is generally admitted that cardiomyocytes damaged by ischemia close their GJ and isolate themselves from surrounding cells.This phenomenon known as "healing over" has been teleologicallyexplained as a defensive mechanism aimed to limit cell-to-celldiffusion of cytosolic derangements. The main evidence of thisphenomenon in myocardium are the changes in its electrical behaviorinduced by ischemia. These changes have been related, at leastin part, to a reduced ability of GJ to allow propagation of theaction potential (4, 10, 24, 45), and their appearanceshows a close temporal association with the development of rigorcontracture (4, 5, 10, 24). Rigor contracture is theresult of the formation of stable, low-energy, Ca²⁺-independent cross bridges between actin and myosin as a consequenceof low ATP availability. It is manifested by an abrupt shorteningin isolated cardiomyocytes and by an increase in rest tensionin in situ myocardium, which occurs when cytosolic ATP concentrationis reduced to a critical threshold level (1). Rigor contracturecontributes itself to the aggravation of ischemic injury by acceleratingATP depletion and promoting cytosolic Ca²⁺ rise (1), and studies in isolated cardiomyocytes demonstratethat the time elapsed between rigor development and restorationof oxygen supply predicts survival or death of cardiomyocytesupon reenergization (44). Thus once ischemic rigor develops,cytosolic Ca²⁺ starts to increase progressively until it reaches a plateau,and shortly after the initiation of Ca²⁺ rise, changes in the electrical behavior of the myocardium appearand progress slowly during the following minutes (5, 10).

The mechanism by which ischemia alters electrical coupling has not been completely elucidated, but increased cytosolic Ca²⁺ concentration is thought to be the most important factor (10,40). Because at the time when rigor develops, Ca²⁺ overload and signs of electrical uncoupling are absent or negligible,the question arises whether GJ communication may allow synchronizationof the onset of rigor contracture across ischemicmyocardium.

Furthermore, the time course of the alterations in GJ permeability occurring during ischemia and the time point at which GJ-mediatedintercellular communication is totally abolished have not beenestablished. This question cannot be easily answered from theanalysis of electrical behavior, mainly due to the complex relationshipbetween changes in the electrical properties of ischemic myocardiumand changes in GJ conductance (39). On the other hand, directmeasurement of GJ conductance in isolated cell pairs by the patch-clamptechnique cannot be performed under true ischemic conditions (43).

The purpose of our study was to investigate whether GJ communication may allow synchronization or cell-to-cell propagationof rigor contracture of cardiomyocytes during energy deprivationand to analyze whether biologically significant GJ-mediated chemicalcommunication may persist in ischemic myocardium after rigor onsetand Ca²⁺ rise. Experiments were conducted in end-to-end connected pairsof isolated myocytes submitted to metabolic inhibition and inisolated rat hearts submitted to global ischemia. The resultsindicate that communication through GJ allows propagation of rigorcontracture from one cell to the adjacent one and that GJs remainpermeable after the development ofrigor.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Handling of animals conformed with the Guide for the Care and Use of Laboratory Animals published by the National Institutesof Health (National Institutes of Health Publication 85-23, Revised1996) and the experimental procedures were approved by the ResearchCommission on Ethics of the Hospital Vall d'Hebron.

Isolated Cardiac Myocytes

Ventricular heart muscle cells were isolated from adult male Sprague-Dawley rats as previously described (16). Simulatedischemia was performed by exposure to either 2 NaCN mM/20 mM 2-deoxyglucose,or dinitrophenol (DNP) 20 µM in glucose-free HEPES buffer at pH6.4. Onset of rigor contracture, GJ permeability, and changesin cytosolic intracellular Ca²⁺ concentration ([Ca²⁺]_i) under metabolic inhibition (MI) were investigated in end-to-endconnected myocytes resulting from incomplete dissociation andwere compared with those observed in pairs of randomly selectednonconnected cells within the same optical field. When a cellpresented a deteriorated appearance, it was excluded from thecomparison. Forty micromoles of the GJ blocker 18 $alpha$ -glycyrrhetinicacid (18 $alpha$ -GA) was added to the MI buffer to analyze the effectof GJ on rigor propagation and subsequent Ca²⁺ rise. This concentration has been shown to efficiently blockdye transfer in noncardiac cells expressing Cx43 (18). We haveobserved that perfusion of isolated rat hearts with 40 µM 18 $alpha$ -GAinduces a rapid reduction in impulse propagation velocity, assessedby analysis of transmembrane action potentials, followed by ventricularfibrillation (unpublished results). To ensure that the effectsof 18 $alpha$ -GA were dependent on its uncoupling properties, two additionalseries of experiments were performed in which GJ were blockedwith the chemically unrelated uncouplers heptanol (2 mM) or oleicacid (50 µM).

Cell morphology, microinjection of Lucifer yellow, and [Ca²⁺]_i measurement. Cell images were continuously video recorded at ×200 magnification on the stage of an inverted microscope (Olympus IX70) at37°C. Changes in cell length were measured on the video-recordedimages in both cells of a pair every 1 s, and the first imagein which cell length changed (i.e., became shorter than the precedentone) was labeled and used to identify rigor onset. Measurementswere expressed as the relative changes in length before MI. Toassess GJ permeability, one of the cells of each pair was microinjectedwith 2% Lucifer yellow (LY) 10 min after rigor development (16,41). Transfer of the dye through GJ was monitored under fluorescencemicroscopy by using a 420-nm excitation light. [Ca²⁺]_i was monitored throughout MI with a ratio fluorescence imagingsystem (QuantiCell 900, Visitech) (42). For this purpose, myocyteswere loaded 20 min at 37°C with 2.5 µM of the fura 2-acetoxymethylester (Molecular Probes) in medium 199, washed twice, and postincubatedfor 10 min in medium 199. After the addition of the metabolicinhibitor, cells were alternatively excited at 340 and 380 nmby means of a fast-speed monochromator. Emitted light was collectedby an air-cooled intensified digital camera with a resolutionof 160 × 160 pixels. 340/380 ratios were calculated for each pixelat 500-ms intervals from background-subtracted signal intensitiesin pairs of images consecutively obtained at the two wavelengths,and color-coded 340/380 ratio images were generated. The averageratio was calculated for regions of interest defined in cell images,and changes in these average ratio values through time were analyzed.The onset of [Ca²⁺]_i rise was identified visually from a curve connecting the lowestvalues in the 340/380 ratiocurve.

Isolated Perfused Rat Heart

Hearts from adult male Sprague-Dawley rats (300-350 g, n = 20) were perfused with a Krebs-Henseleit bicarbonate buffer at37°C at 60 mmHg (19). Left ventricular (LV) pressure was monitoredby means of a water-filled latex balloon placed in the left ventricleand connected to a pressure transducer (19). After 15 min ofequilibration, hearts were submitted to nonflow ischemia at 37°Cor to 45 min of normoxic perfusion at pH 7.4 (control) or at pH6.4 (acidosis). In an additional series of experiments, 18 $alpha$ -GAat either 10 or 40 µM was added during 30 min to the normoxicperfusionbuffer.

Loading of LY and rhodamine dextran in the whole heart. Assessment of GJ permeability in myocardial tissue was performed by a modification of a previously described method (13,14). Two fluorescent dyes, rhodamine-conjugated dextran (RD)and LY, were used to quantify diffusion through GJ from previouslymarked cells in which dye loading had been performed by a directexposure after mechanical damage. Because of its high molecularweight (10,000), RD cannot diffuse through GJ and remains circumscribedto cells with broken sarcolemma, whereas LY (molecular weight,457) acts as a tracer for diffusion through GJ channels. In aseries of experiments, 30 min after the onset of rigor (~45 minof ischemia) the whole hearts were placed in phosphate-bufferedsaline (PBS) containing 2.5 mg/ml RD and 2.5 mg/ml LY at 37°Cand continuously gassed with N₂. A deep incision in the LV wallwas made in each heart from base to apex with a surgical blade,and direct exposure to the anoxic dye containing buffer was allowedfor 10 min. After dye loading, hearts were washed in PBS and fixedin 25% Karnovsky's solution for 4 h. In other series of ischemichearts, the excision and dye loading were performed after 2 hof ischemia. For normoxic hearts, the N₂ used to gas solutionswas replaced by O₂.

Tissue processing and laser confocal microscopy. Fixed tissue was frozen by immersion in hexane cooled with liquid N₂ and stored at $-$ 80°C. Sixty-micrometer transversal sectionsincluding the whole right and left ventricles were obtained witha cryostat (Leica CM1325) and mounted on glass. Tissue sectionswere examined by using a confocal laser scanning microscopy (DMRIBELeica, software TCS-NT) equipped with an argon-krypton gas laser.FITC and tetramethylrhodamine isothiocyanate excitation filterswere selected to discriminate between LY (Ex488/515) and RD (Ex568/590)signals, and two separated 1,024 × 1,024 digital images per slicewere obtained at ×10. The difference between the area of distributionof LY fluorescence and the area of distribution of RD fluorescencewas quantified with commercially available software (Olympus Microimage)and expressed as a fraction of the area of RD distribution asan index of GJpermeability.

Statistics

Statistical analysis was performed with the aid of commercially available software (SPSS for Windows). Comparisons betweengroups were performed by ANOVA and the Student-Newman-Keuls test.A critical P value of 0.05 was used in all comparisons. Data areexpressed as means ±SE.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Cell-to-Cell Propagation of Rigor Contracture

The average time at which rigor appeared was not different in connected cells with respect to single cells (1,097.5 ± 70.8vs. 938.5 ± 66.8 s, P = not significant). In end-to-end connectedcell pairs submitted to MI, development of rigor contracture inone cell was consistently followed by near-simultaneous developmentof rigor contracture in the adjacent cell (Fig. 1). This temporalassociation between rigor onset in end-to-end connected cellswas observed independently of the inhibitor used (NaCN or DNP),although rigor appeared earlier in cells exposed to DNP comparedwith those exposed to NaCN. The average difference in time betweenthe onset of rigor in two cells forming a connected pair duringMI was 3.70 ± 0.75 s (n = 30). In contrast, in nonconnected cellsrandomly selected within the same optical field this intervalwas 71 ± 11.7 s (n = 14). The involvement of GJ in the temporalassociation of rigor onset in connected cells was investigatedby adding the GJ blocker 18 $alpha$ -GA to the MI buffer. The presenceof 18 $alpha$ -GA significantly increased the time elapsed between bothcells in the development of rigor contracture (Fig. 2) withoutaffecting the average time at which rigor appeared (648.6 ± 163.8s in the absence of 18 $alpha$ -GA vs. 568.8 ± 90 s in its presence, P= not significant). Similar results were obtained when inhibitionof GJ communication was performed with either heptanol or oleicacid (interval between rigor onset in connected cell 11.5 ± 3.4s, n = 17, and 11.3 ± 2.7 s, n = 3, respectively).

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Fig. 1. Temporal association in the onset of rigor contracture in end-to-end connected cardiomyocytes submitted to metabolic inhibition (MI) (2 mM NaCN /20 mM 2-deoxyglucose, pH 6.4). There was an excellent correlation between the duration of exposure to MI before the onset of rigor contracture in the 2 end-to-end connected cells ( $black-triangle$ ). This close association was not observed between pairs of randomly selected nonconnected cells within the same optical field ( $triangle$ ). r, Pearson correlation coefficient.

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Fig. 2. Time interval between the onset of rigor contracture in connected cell pairs submitted to MI with 20 µmol/l dinitrophenol (DNP). The presence of 40 µmol/l 18 $alpha$ -glycyrrhetenic (18 $alpha$ -GA) during MI significantly increased the time elapsed between the onset of rigor in cell 1 (C1) and in the adjacent cell 2 (C2). Results are expressed as means ± SE from 9 and 15 experiments per group.

To investigate whether the temporal association in rigor onset was the result of the synchronization in the progression ofinjury or reflected cell-to-cell propagation of rigor, we examinedthe degree of shortening in the cell that initiates rigor andin the adjacent cell. It was assumed that if rigor developed synchronouslybut independently in two connected cells, the magnitude of shorteningshould be equal in both cells. On the contrary, a significantassociation between the magnitude of shortening and the orderof rigor onset would indicate directionality, i.e., propagation.This was indeed the case: when cells were connected, the degreeof shortening of the adjacent cell was less pronounced than thatobserved in the cell initiating the rigor. As expected, therewas no association between the order of initiation of rigor andthe magnitude of shortening in the case of nonconnected cell pairs(Fig. 3). In connected pairs, 18 $alpha$ -GA had a clear influence onthe shortening of the cell developing rigor in the second place.However, the direction of this influence was toward a greaterdifference in the percentage of shortening compared with controlcell pairs. The same result was obtained with heptanol and oleicacid (Fig. 3).

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Fig. 3. Difference between the magnitude of shortening (percentage of change with respect to length before MI) in the cell that initiates rigor (C1) with respect to its pair (C2) when considering nonconnected cell pairs (n = 9) or end-to-end connected cell pairs submitted to MI (DNP 20 µM) without addition of a gap junction (GJ) blocker (n = 14) or in the presence of 18 $alpha$ -GA (n = 15), heptanol (n = 17) or oleic acid (n = 3). When cells were not connected, shortening was similar in both of them (P = not significant, null hypothesis, difference in shortening not different from 0). On the contrary, in end-to-end connected cells, shortening of the adjacent cell was significantly less pronounced than that observed in the cell that first goes into rigor. Addition of any of the GJ blockers used in this study did not abolish or even exaggerate this difference. Results are expressed as means ± SE. *P < 0.05, null hypothesis, difference in shortening not different from 0.

Equilibration of [Ca²⁺]_i Rise and LY Diffusion in Connected Cell Pairs

During MI, [Ca²⁺]_i remained unchanged until the onset of rigor contracture. Rigor was associated to a marked increase in [Ca²⁺]_i. In connected cell pairs, the time course of [Ca²⁺]_i was virtually identical in both cells, with an excellent correlationbetween the time to the onset of [Ca²⁺]_i rise in both cells (r² = 0.99, n = 18). In contrast, in nonconnected cells within thesame optical field the magnitude and time-course of [Ca²⁺]_i rise showed a great variability (r² = 0.49, n = 14) (Fig. 4). In the presence of 18 $alpha$ -GA, the curvesof [Ca²⁺]_i in connected cells tended to diverge as the time of MI progressed,and the difference between ratios in the two cells was significantlyhigher in the presence of 18 $alpha$ -GA (0.293 ± 0.08 vs. 0.064 ± 0.01,P = 0.022, Fig. 5). These results suggest that GJ communicationpersists after the onset of rigor contracture. After microinjectionof 2% LY in one of the cells of the pair 10 min after rigor development,there was dye transfer in six of seven pairs (85.7%) of end-to-endconnected myocytes, confirming chemical coupling after rigor development(Fig. 6).

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Fig. 4. A: sequence of 3 fura 2 images in a pair of end-to-end connected cardiomyocytes and a single nonconnected cell submitted to MI with 20 µM DNP, just before (0 s) and up to 30 s after rigor onset. B: values of 340/380 ratio in these cells along time. Rigor and [Ca²⁺]_i rise in one cell of the pair was immediately followed by the corresponding changes in the other cell. In the single cell, these changes followed a different pattern. ID, intercalated disk. Arrows correspond to times at which the ratio fluorescence images shown in A were obtained.

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Fig. 5. Difference in the 340/380 ratio between two cells of an end-to-end connected pair loaded with fura 2 and submitted to MI with 20 µM DNP, reflecting differences in the magnitude of intracellular Ca²⁺ concentration ([Ca²⁺]_i) rise among them. The 0 in the time axis corresponds to the onset of rigor shortening. In the absence of the GJ blocker 18 $alpha$ -GA the difference in the 340/380 ratio between both cells remained constant and close to 0, indicating that both cells developed the same degree of [Ca²⁺]_i overload. Addition of 18 $alpha$ -GA was associated to an increasing difference in the 340/380 ratio. Curves represent the average of 7 and 12 cell pairs, respectively.

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Fig. 6. Sequences of images obtained after microinjection of Lucifer yellow (LY) in a pair of connected cardiomyocytes during MI. LY was microinjected in cell 1 10 min after rigor onset and diffused to the adjacent cell (cell 2) in less than 30 s, demonstrating that the GJ remained permeable. All arrows indicate the ID. The graph shows the increase in fluorescence intensity in both cells after microinjection. au, Arbitrary units.

Persistence of GJ Permeability in Ischemic Rat Hearts

LY diffusion was assessed in isolated rat hearts submitted to nonflow ischemia at 37°C. The abrupt increase in LV end-diastolicpressure occurring after 16.8 ± 1.1 min was considered the invivo marker of the development of rigor contracture. Thirty minutesafter rigor onset (~45 min of global ischemia), the differencebetween the extent of LY diffusion in each slice (from the incisionmade for dye exposure to the adjacent myocardium) and the RD diffusion(circumscribed to myocytes with broken sarcolemma) was 2.97 ±1.27 (n = 8). This value was similar to that obtained in normoxichearts (3.58 ± 1.33, n = 4), demonstrating diffusion of LY tocells located far away from those with disrupted sarcolemma underischemic conditions (Fig. 7). However, when hearts were submittedto 2 h of global ischemia, the area of LY diffusion was coincidentwith the area of RD diffusion (the difference in the area of diffusionbetween both dyes was 0.10 ± 0.01, n = 2). Acidotic perfusionwithout ischemia resulted in a marked reduction of GJ permeability(the difference in the area of LY diffusion and RD diffusion was0.91 ± 0.37, n = 2) (Fig. 8). Addition of 18 $alpha$ -GA at 10 or 40 µMduring normoxic perfusion did not abolish LY transmission, althoughit resulted in a reduction in its diffusion (the differences betweenLY diffusion and RD diffusion were 1.5 ± 1.25 and 0.88 ± 0.28,respectively, P < 0.05 in respect to controls, n = 4).

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Fig. 7. Cell-to-cell dye diffusion in the rat heart during normoxia (A1, B1) and 30 min after development of ischemic rigor contracture (A2, B2). The addition of rhodamine dextran (RD) (red area) corresponds to cells with disrupted sarcolemma. These cells were mainly distributed along the border of myocardial incision exposed to the dyes. The infusion of LY (green area) represents intercellular dye diffusion through GJ to cells located far from the border of the incision. The area of diffusion of LY in hearts submitted to 45 min of ischemia (B2) was similar to that observed in normoxic controls (B1), confirming that myocytes remained chemically coupled after rigor development. Analysis at higher magnification shows diffusion of LY between end-to-end connected cardiomyocytes (B3). Arrows indicate the intercalated disk.

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Fig. 8. Diffusion of LY in intact rat hearts. The areas of RD fluorescence denoting sarcolemmal rupture, and of LY fluorescence denoting GJ-mediated dye transfer are shown in the different groups of treatment. Control, normoxic perfusion; acidosis, normoxic perfusion at pH 6.4; Isch-45 min and Isch-2 h, global ischemia of different durations. Inset, relative difference between both areas in the same groups. *P < 0.05.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The results of this study show that in end-to-end connected cardiac myocytes submitted to MI, the development of rigor contracturein one of the cells is systematically followed within a few secondsby the development of rigor contracture in the adjacent cell.This close temporal association between onset of rigor contrastedwith the large variability in the time of rigor onset observedin nonconnected cells within the same optical field and was sensitiveto the GJ uncoupler 18 $alpha$ -GA. The curves of [Ca²⁺]_i rise observed after rigor onset varied from cell to cell, butwere virtually superimposable in the two cells connected forminga pair, suggesting that GJ communication allows equalization ofionic cytosolic concentrations after the development of rigorcontracture. Microinjection of 2% LY in one of the two connectedcells 10 min after rigor onset demonstrated persistent dye coupling.LY transfer was also documented 30 min after the onset of rigorcontracture in isolated rat hearts submitted to nonflow globalischemia. Altogether, these results are in agreement with thehypothesis that GJ may allow cell-to-cell propagation of rigorcontracture and equalization of Ca²⁺ overload in ischemiccardiomyocytes.

Propagation of Rigor Contracture

Contracture appears during energy depletion as the consequence of the formation of low energy Ca²⁺-independent bonds between actin and myosin when decreasing ATPconcentration reaches a critical value. Studies in rabbit papillarymuscle and in situ porcine myocardium have shown that in ischemicmyocardial tissue, signs of electrical uncoupling such as slowingof impulse propagation and increased intracellular resistanceare absent during the first minutes of ischemia and appear onlyafter development of rigor contracture and [Ca²⁺]_i rise (4, 10). Because GJ are permeable to most physiologicallyrelevant ions, intracellular messengers, and high-energy compoundsincluding ATP, it is not surprising that continuous equilibrationof cytosolic composition between adjacent ischemic myocytes resultsin uniform progression of ischemic injury. Synchronization ofthe onset of rigor contracture may thus reflect the uniform progressionof injury, but can also be the consequence of cell-to-cell propagationof rigor contracture through GJ-mediated communication. Attenuatedmagnitude of rigor shortening in the cell that develops rigorin the second place within a cell pair suggests that this is indeedthe case. The present findings do not provide information on themessenger responsible for propagation of rigor. There is a lackof candidates to play this role, because rigor is not due to accumulationof any substance, but to ATP depletion. However, ATP consumptionby rigor bonds in one cell should be expected to generate an intercellulargradient in cytosolic ATP concentration. It can be speculatedthat this gradient drives the passage of ATP from the adjacentcell, therefore reducing its cytosolic ATP concentration to therigor threshold. However, the attenuated magnitude of rigor shorteninginduced by uncouplers in the adjacent cell is difficult to explainwithin this hypothesis. One possibility is that the rate of ATPdepletion may influence the ATP level at which rigor starts. Uncouplerswould reduce the ATP transfer between cells and the rate of ATPdepletion in the second cell induced by development of rigor inthe firstone.

GJ-mediated Communication After Rigor Onset

The present observation that GJ-mediated intercellular communication may persist after the development of ischemic rigor contractureand [Ca²⁺]_i rise in cardiomyocytes challenges the notion that healing overprevents cell-to-cell communication among severely ischemic cardiomyocytes.This notion is based on several lines of evidence. In the firstplace, detailed cable analysis of myocardial preparations (4,10, 24, 45) and in vivo studies (5) show that developmentof ischemic rigor contracture is consistently associated to theappearance of progressive abnormalities in electrical tissue resistanceand impulse propagation (4, 5, 10, 24). These abnormalitiesprogress slowly during the minutes after the development of rigor.In the isolated papillary muscle, conduction block and maximaltissue resistance are reached only after 10-20 min of rigor contracture(4, 10). In in situ ischemic porcine myocardium, electricalimpedance (phase angle shift) rises steadily during the 90-120min after rigor onset (5). The slow progression of electricalabnormalities could reflect, in part, a progressive decrease ofGJ conductivity compatible with the present findings. Moreover,complete blockade of impulse propagation may occur before GJ conductivityreaches 0 (10, 39, 45). Changes in net inward and outwardcurrents (e.g., activation of ATP-sensitive K⁺ current) depressing excitability, as well as altered extracellularresistance, intracellular resistance, and membrane capacitancemay all contribute to the altered electrical behavior in ischemicmyocardium (10, 39, 45). Under certain circumstances suchas current-to-load mismatch, conduction block may occur in thepresence of normal GJ conductance (38).

Studies in isolated cell pairs and cell expression systems have demonstrated that conductance of Cx43 channels is reducedby increased cytosolic concentrations of H⁺ (15) and Ca²⁺ (40), by depletion of ATP (43), and by accumulation of amphipathicmetabolites (9), which are abnormalities that concur in ischemicmyocardium. However, the mechanisms by which these stimuli influenceGJ permeability have not been established. Interactions occurringamong these abnormalities (3) and alterations in intracellularsignaling caused by ischemia (11) prevent a direct extrapolationof the results of these studies to myocardial tissue. For example,exposure to pH 6.4 under normal extracellular Ca²⁺ abolishes Cx43 conductivity (15), whereas no abnormality inimpulse propagation is observed during the first minutes of myocardialischemia despite a severe acidosis. On the other hand, the relationshipbetween GJ permeability and low-resistance electrical communicationthrough GJ is also complex, and regulatory mechanisms may haveopposed effects on electrical and dye coupling if they have opposedeffects on the probability of the open state of GJ channels andthe size of opening (11, 28, 29). Thus although there issolid evidence that ischemia increases GJ resistance, the availableinformation is compatible with persistent chemical communicationthrough GJ in severely ischemic, rigor-contractured myocardium.The mechanism by which GJ may remain permeable in ischemic myocardiumdespite acidosis, Ca²⁺ overload, ATP depletion, and accumulation of amphipathic catabolitescannot be elucidated by this study. It can be speculated thatthe modification of the phosphorylation status of Cx43 causedby ischemia impairs its regulation by these stimuli. Ischemiarapidly reduces the phosphorylation status of different importantproteins. Inhibition of phosphatases has been found to be protectiveagainst different manifestations of ischemic injury (2, 30,46), whereas activation of protein kinases seems an essentialstep in the protective effect of ischemic preconditioning (47).There is strong evidence that GJ gating may be regulated by changesin connexin phosphorylation. Also, there is compelling evidencethat phosphorylation of Cx43 by different protein kinases, includingmitogen-activated protein kinase and p34 kinase, reduces GJ communication(21, 23, 27, 31), whereas dephosphorylation increasesit (8). It has been recently described (12) that phosphorylationof Cx43 in cardiomyocytes depends on the epsilon subtype of proteinkinase C (PKC- $epsilon$ ). The inhibitory effects of Cx43 phosphorylationon GJ communication could be involved in the protective effectof interventions such as ischemic preconditioning, a beneficialeffect that appears to be mediated by activation of protein kinases,particularly the PKC- $epsilon$ isoform. These observations suggest thatphosphorylation of Cx43 at specific sites induces conformationalchanges that affect its gating properties. The present observationthat exposure to acidotic perfusion reduces GJ permeability inintact rat myocardium during normoxic conditions, whereas ischemiaof the same duration, expected to result in pronounced acidosis,does not reduce GJ permeability, supports thishypothesis.

The results of the present study are in agreement with recent observations demonstrating the persistence of GJ communicationduring ischemic conditions in tissues other than myocardium. Severalstudies have shown that GJ coupling during cerebral ischemia canresult in an amplification of cell injury (7, 32, 36).Using a model of cultured astrocytes, Cotrina et al. (7) foundthat coupling was reduced but never abolished after 2 h of MIand that chemical communication through GJ occurred up to theterminal loss of membrane integrity. Interestingly, lowering pHto 6.0 caused no detectable decrease in GJ permeability. Chemicalcoupling in astrocytes was corroborated in hippocampal slicesduring ischemic conditions. Similar results (32) were obtainedin neocortices of rats after applying the technique of fluorescentrecovery after photo bleaching. Although a decrease in fluorescencerecovery (reflecting a decreased diffusion through GJ) was observed,Lin et al. (32) found that astrocytic GJ remains open in theanoxic brain. The contribution of GJ to the expansion of injuryis an emerging field. It has been described that GJ coupling mayresult in amplification of injury due to causes other than ischemia.There is evidence that cell-to-cell communication can mediatethe death of tumor cells adjacent to those directly targeted bydifferent antineoplastic treatments (bystander effect) (17,34, 37). Previous studies (16, 41) had shown that GJ-mediatedcommunication allows spreading of cell injury during myocardialreperfusion.

Study Limitations

In the present study, GJ uncouplers failed to completely abolish dye transfer and delayed, but did not prevent, propagationof rigor contracture. This limitation is difficult to circumventbecause there is a lack of substances proven to be able to completelyblock dye coupling in end-to-end connected cardiomyocytes or inmyocardium. Another potential limitation is that metabolic inhibitionor ischemia could open undocked hemichannels and allow LY loadingfrom the extracellular space (25). This possibility seems extremelyunlikely in our study because in previous observations cardiomyocytessubmitted to prolonged metabolic inhibition (60 min) failed tobecome loaded with LY present in the extracellularmedium.

The present results demonstrate that, contrary to expectations, cardiomyocytes can communicate with their counterparts alsoduring ischemia and this communication persists after the onsetof rigor contracture, a critical period when survival or deathresponse to subsequent reperfusion is defined. These results addto previous observations showing that during reperfusion, transjunctionalmovements of Na⁺ may result in propagation of cardiomyocyte hypercontracture (41)and that inhibition of GJ communication during initial reperfusionmay limit infarct size (16). Altogether these studies indicatemyocardium may respond to a large extent as a functional syncytiumto ischemia-reperfusion. This previously neglected cellular interactionmight represent a more generalized mechanism of spreading cellinjury in tissues with well-developed cell-to-cell communication.Understanding the biochemical basis of such interaction shouldprovide insight into the role of GJ in the progression of ischemicinjury and open the possibility of new therapeuticapproaches.

	ACKNOWLEDGEMENTS

We thank Yolanda Puigfel for excellent technicalassistance.

	FOOTNOTES

This work was supported by the PL95-1254 BIOMED-2 program of the European Union and by Grant SAF99/0102 from the ComisiónInterministerial de Ciencia y Tecnología,Spain.

Address for reprint requests and other correspondence: D. Garcia-Dorado, Dept. of Cardiology, Hospital Vall d'Hebron, Pg.Vall d'Hebron 119-129, Barcelona 08035, Spain (E-mail: dgdorado{at}hg.vhebron.es).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 22 September 2000; accepted in final form 22 January 2001.

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