Matrix metalloproteinase synthesis and expression in isolated LV myocyte preparations.

In several cardiac disease states, alterations in myocyte and extracellular matrix (ECM) structure occur with left ventricular (LV) remodeling and are associated with changes in matrix metalloproteinase (MMP) activity. Although nonmyocyte cell types have been implicated as sites for synthesis and expression of MMPs within the ECM, whether the LV myocyte itself expresses specific types and active forms of MMPs remains unknown. Accordingly, isolated Ca(2+)-tolerant LV porcine myocytes (10(5) cells/ml) in which selective disaggregation and resuspension was performed (13 independent experiments) were plated on basement membrane substrates including Matrigel, collagen IV, laminin, and fibronectin as well as poly-L-lysine. After 24-h incubation, LV myocyte conditioned media were subjected to zymography, a specific MMP-2 proteolytic capture assay, immunoblotting, and ELISA for detection of MMP activity and relative content of the 72-kDa gelatinase MMP-2. Although robust zymographic activity [(pixels. mm(2))/cell] was observed in conditioned media from LV myocytes plated on collagen IV (1,673 +/- 297), fibronectin (1,530 +/- 281), and poly-L-lysine (2,545 +/- 560), proteolytic activity appeared to be lower in conditioned media from LV myocytes plated on Matrigel (842 +/- 83) and laminin (1,329 +/- 238). MMP-2 proteolytic activity was increased by approximately eightfold in conditioned media taken from LV myocytes plated on poly-L-lysine compared with that of Matrigel. With respect to each of the adhesion substrates, MMP-2 content was at least 50% lower in LV myocyte conditioned media taken from Matrigel and laminin. Immunofluorescent labeling of LV myocytes yielded a strong signal for MMP-2 within the myocyte and along the sarcolemmal surface. In conclusion, this study demonstrated for the first time that adult LV myocytes synthesize and express members of the MMP family and thus may potentially participate in the LV remodeling process through synthesis and secretion of MMPs.

Normothermic versus hypothermic hyperkalemic cardioplegia: effects on myocyte contractility.

BACKGROUND: This study was designed to determine the effects of prolonged hyperkalemic cardioplegic arrest under normothermic or hypothermic conditions with respect to left ventricular myocyte contractile performance and beta-adrenergic responsiveness. METHODS: Isolated left ventricular porcine myocytes were randomly assigned to one of three groups: (group 1) normothermic control, (group 2) hypothermic cardioplegic arrest, or (group 3) normothermic cardioplegic arrest. Myocyte contractility was evaluated by high-speed video microscopy at baseline and after beta-adrenergic stimulation with isoproterenol (25 nmol/L). RESULTS: Myocyte velocity of shortening was decreased after both hypothermic and normothermic cardioplegic arrest (68 +/- 2 and 69 +/- 2 microns/s, respectively) compared with normothermic control values (96 +/- 2 microns/s; p < 0.05). This relative reduction in baseline contractile function was equivalent in both cardioplegia groups (p = 0.5356). With beta-adrenergic stimulation, myocyte velocity of shortening was 186 +/- 4 microns/s in the hypothermic and 176 +/- 3 microns/s in the normothermic cardioplegia groups (p = 0.0563). However, myocyte contractility with beta-adrenergic stimulation was reduced in both cardioplegia groups compared with normothermic controls (205 +/- 4 microns/s; p < 0.05, respectively). CONCLUSIONS: Hyperkalemic cardioplegic arrest under either normothermic or hypothermic conditions resulted in an equivalent reduction in baseline myocyte contractile function with reperfusion/rewarming. Hypothermic cardioplegic arrest may have provided mild protective effects on beta-adrenergic responsiveness. Nevertheless, these results suggest that an important contributory factor for diminished myocyte contractility after simulated cardioplegic arrest was prolonged exposure to a hyperkalemic environment.

Downstream defects in beta-adrenergic signaling and relation to myocyte contractility after cardioplegic arrest.

OBJECTIVE: Transient left ventricular dysfunction can occur after hypothermic, hyperkalemic cardioplegic arrest and is associated with decreased beta-adrenergic receptor responsiveness. Occupancy of the beta-adrenergic receptor activates adenylate cyclase, which phosphorylates the L-type Ca2+ channel-enhancing myocyte contractility. The goal of this study was to identify potential mechanisms that contribute to the defects in the beta-adrenergic receptor signaling cascade after cardioplegic arrest. METHODS: Isolated left ventricular porcine myocytes were assigned to one of two treatment groups: (1) cardioplegic arrest (24 mEq/L K+, 4 degrees C x 2 hours, then 5 minutes in 37 degrees C cell media; n = 130) or (2) normothermic control (cell media, 37 degrees C x 2 hours; n = 222). Myocyte contractility was assessed at baseline and after either beta-adrenergic receptor occupancy (25 nmol/L isoproterenol [INN: isoprenaline]), activation of adenylate cyclase (0.5 mumol forskolin), or direct activation of the L-type Ca(2+)-channel (10 nmol/L or 100 nmol/L (-)BayK 8644). RESULTS: Myocyte velocity of shortening (micron/sec) was increased with beta-adrenergic receptor occupancy or direct adenylate cyclase stimulation compared with baseline in the normothermic group (187.3 +/- 6.9, 181.7 +/- 10.2, and 73.9 +/- 2.9, respectively; p < 0.0001) and after cardioplegic arrest (128.6 +/- 8.9, 124.3 +/- 9.4, and 46.1 +/- 2.6, respectively; p < 0.0001). However, the response after cardioplegic arrest was significantly reduced compared with normothermic values under all conditions (p = 0.012). Direct activation of the L-type Ca(2+)-channel, which eliminates beta-adrenergic receptor-dependent events, increased myocyte contractility in the normothermic group (161.90 +/- 12.0, p < 0.0001) and after cardioplegic arrest (92.78 +/- 6.8, p < 0.0001), but the positive inotropic response appeared reduced compared with normothermic control values (p = 0.003). CONCLUSION: These findings suggest that contributory mechanisms for the reduced beta-adrenergic receptor-mediated response after hypothermic, hyperkalemic cardioplegic arrest lie downstream from these specific components of the transduction pathway and likely include defects in Ca2+ homeostasis, myofilament Ca2+ sensitivity, or both.