Regulation of adult cardiocyte growth: effects of active and passive mechanical loading.

Fluctuations in hemodynamic load have been documented to modulate contractile protein turnover and myofibrillar structure in the heart; however, the relative importance of active and passive loading in regulating adult cardiocyte growth remains unresolved. To address this issue at the cellular level, adult feline cardiocytes were cultured either on Silastic membranes or plastic surfaces. Cardiocyte-laden membranes were stretched 10% of their rest length to enhance passive loading, whereas heart cells cultured on plastic or Silastic were field stimulated at 1 Hz to mimic active loading. Turnover of contractile proteins and structural integrity of the contractile-cytoskeletal apparatus were monitored for periods ranging from 4 to 72 h. Active and passive loading elevated contractile protein synthesis nearly equally (approximately 50%) and promoted the attachment of remodeled myofibrils to vinculin-positive focal contacts and/or costameres during the first 24 h of loading. Thereafter, rates of contractile protein synthesis returned to control values in passively stretched heart cells but remained elevated in field-stimulated cultures. The fractional rate of growth was increased significantly (approximately 8%/day) in electrically paced cells, whereas in passively stretched cardiocytes the growth rate rose only modestly (approximately 2%/day). Changes in the rate of myocyte growth appeared more closely correlated with the development of focal contacts and myofibril remodeling than with changes in myofibrillar protein turnover per se. 2,3-Butanedione monoxime, nifedipine, and, to a lesser extent, ryanodine blocked field-stimulated contractile protein synthesis and myofibrillar remodeling but had no impact on protein turnover or myofibril reassembly in passively loaded cardiocytes. The results of these experiments imply that both active and passive loading stimulate contractile protein turnover and myofibril remodeling, but the generation of active tension accelerates cardiocyte growth to a greater extent than passive loading. Furthermore, pharmacological interventions suggest that unique pathways may mediate these cellular events in actively and passively loaded adult cardiocytes.

Catecholamines modulate protein turnover in cultured, quiescent rabbit cardiac myocytes.

When rabbit ventricular myocytes were cultured for 1 wk and then exposed to alpha- and/or beta-adrenergic agonists, such nonbeating heart cell preparations disclosed increased protein-to-DNA ratios and elevated RNA content, indicative of cellular hypertrophy. Norepinephrine, isoproterenol, and phenylephrine provoked hypertrophy with norepinephrine eliciting a greater response than isoproterenol or phenylephrine. Specific alpha- and beta-antagonists blocked growth by inhibiting catecholamine-induced changes in protein turnover. Each catecholamine enhanced the fractional rate of protein synthesis within 48 h; however, changes in growth rates appeared to be modulated, in part, by alterations in protein degradation. Even though rates of total protein and actin synthesis resembled values measured in vivo, myosin heavy chain fractional rate of synthesis was only 22% of in vivo levels. Double label immunofluorescence microscopy further illustrated that catecholamine treatment accelerated myofibrillar disruption in these quiescent heart cells. These observations suggested that in the absence of beating, neurohumoral modulation of contractile protein turnover was not associated with the maintenance of myofibrillar integrity even though catecholamines induced cellular hypertrophy.