Altered transarcolemmal Ca transport modifies the myofibrillar ultrastructure and protein metabolism in cultured adult ventricular cardiomyocytes.

The present study was designed to investigate how prolonged (24-72 h) exposure to modifiers of Ca transarcolemmal transport affects the myofibrillar structure, protein turnover and content of myofibrillar proteins in adult guinea pig cardiomyocytes maintained beating synchronously in long-term cultures. First we established the functional responses (the contractile activity and [Ca]i transients) of the cultured myocytes to acute exposures to several drugs used in this study. The ultrastructural characteristics of these cultures under the various treatments were determined using immunohistochemistry and confocal scanning laser microscopy, and their biochemical properties were evaluated using analysis of total cellular protein content, myofibrillar protein content and SDS-PAGE electrophoretic examination. We compared the effects of 24, 36 and 72 h-long exposures to the various specific Ca-flux modifiers. Increased Ca influx via CaL-channel agonist (Bay K 8644) or via the reversed-mode of the Na/Ca exchanger (veratrine) did not alter the myofibrillar structure or the specific protein profiles or proteosynthesis. However, when cytosolic Ca was increased by three different types of inhibitors of Ca extrusion from the cells via Na/Ca exchange, (Na-free solution, 5 mM NiCl2 and 10(-6) M ouabain), very significant changes in all investigated parameters occurred almost immediately. Twenty-four h-long exposure to Na-free did not affect significantly the total cellular protein (TCP), but the protein synthesis was decreased by 87% and the total myofibrillar protein (TMP) content was decreased by 38%. The myofibrils were heavily fragmented. Similarly, 24 h-long exposure to 5 mM NiCl2 did not affect the TCP, but it reduced protein synthesis by about 90% and decreased the total myofibrillar protein content by 30%. These effects were even more pronounced at 72 h of exposure and they were accompanied with a complete disassembly of myofilaments. Exposure to 10(-6) M ouabain over 72 h resulted in > 80% inhibition of protein synthesis, a 45% decrease in TCP content and a 53% in TMP content. In contrast, 10(-7) M ouabain did not produce any such changes. The changes produced by the Na/Ca-exchange inhibitors were accompanied by only minor changes in DNA content, indicating that the myocytes remained viable. Moreover, these effects were not due to the associated contractile arrest, since exposure to CaL-channel antagonists (5-20 microM nifedipine or 10 microM verapamil) produced only very minor changes in the myofibrillar structure and in protein profiles. Our data demonstrate that short-term (up to 72 h) increased Ca influx or contractile arrest of well-interconnected, spontaneously beating adult cardiomyocytes does not affect their ultrastructural characteristics or their myofibrillar protein turnover greatly, while any situations leading to Ca accumulation (via inhibition of Na/Ca exchange) affect cardiomyocyte function and ultrastructure almost immediately. These data are in sharp contrast to those previously reported from immature, neonatal myocytes.