Catecholamine-induced beating and myocardial hypertrophy were evaluated in isolated adult feline cardiomyocytes maintained in culture for up to 30 days. Adult feline cardiomyocytes were used in this study because they displayed several unique characteristics that facilitated assessment of factors regulating cardiomyocyte hypertrophy in vitro. These characteristics included the following. 1) A single heart provides a high yield of 20-40 x 10(6) calcium-tolerant rod-shaped myocytes. 2) In culture, isolated adult feline cardiomyocytes maintain a stable population of differentiated myocytes that could be maintained without the dramatic loss of cell number, DNA content, or cell structure seen in adult rat cardiomyocyte cultures. 3) Cultured feline cardiomyocytes remained quiescent in culture unless appropriately stimulated to begin beating. 4) Sustained regular beating activity could be readily initiated up to 3 wk in culture by addition of 1 x 10(-5) M isoproterenol, other beta-adrenergic agonists, or agents known to elevate adenosine 3',5'-cyclic monophosphate. Beating could be maintained indefinitely in the presence of isoproterenol, but ceased upon removal of isoproterenol from the medium. Initiation of beating in 7-day-old cultures resulted in a profound restructuring of cardiomyocyte morphology compared with quiescent cultures. Beating heart cells were 66% larger with increased protein content, and they had significantly greater development of striated myofibrillar structure than quiescent myocytes at the same age in culture. We conclude that maintenance of an organized myofibrillar structure in cultured adult cardiac myocytes requires activation of intrinsic beating. Cardiomyocyte hypertrophy also develops following beta-adrenergic activation of beating, but it is unclear whether beating per se is required for inducing hypertrophy in isolated adult cardiomyocytes in vitro.
The ability of transient temperature variations for up to 120-min duration to affect myocardial protein synthesis (MPS) with return to normal temperatures was evaluated using 14C-phenylalanine incorporation into total protein of isolated rabbit right ventricular papillary muscles as in vitro model. Muscles were incubated in oxygenated Krebs-Ringer bicarbonate buffer containing tracer amino acid at temperatures of 28-43 degrees C or incubated without tracer at the same temperatures for up to 120 min and then incubated at 37 degrees C for an additional 2 hr with the tracer amino acid present for the final hour of incubation. Higher as well as lower than physiological temperatures depressed MPS. Recovery from thermal injury to MPS was significantly incomplete when the experimental temperature deviated by 6 degrees C or more from the control (28 and 43 degrees C, respectively) and exposure exceeded 60-min duration. Specific activity of the intracellular amino acid pool was directly measured, and variations in specific activity of the tracer pool were not responsible for the observed effects on MPS. Methylprednisolone (10(-5)M), chloroquine phosphate (10(-5) M), and glucose (15 mM) if present during hyperthermia did not ameliorate thermal damage. It is concluded that hypothermia causes inhibition as well as a degree of irreversible inactivation of the protein synthetic mechanism whereas hyperthermia causes predominant denaturation and irreversibile damage to MPS.
Two cases of secondary hypertrophic osteoarthropathy associated with alcoholic liver disease without cirrhosis are reported. Conditions which can be associated with hypertrophic osteoarthropathy and theoretical factors which can play a role in its pathomechanism are briefly discussed.
To examine the effects of cysteine protease inhibitors on cathepsin D intracellular transport, proteolytic processing, and secretion, primary cultures of rabbit cardiac fibroblasts were grown to confluence and exposed (24 h) to media containing leupeptin (0-10 mM), E 64 (0-10 mM), or chloroquine (0-50 microM). Cathepsin D maturation was then evaluated in pulse-chase biosynthetic labeling experiments. None of the three agents affected the charge modification of procathepsin D (Mr 53,000) within the Golgi apparatus. However, all three agents interfered with the subsequent proteolytic processing of procathepsin D isoforms to active cathepsin D (Mr 48,000). Both leupeptin and E 64 caused the intracellular accumulation of large amounts of a Mr 51,000 processing intermediate (not detectable in control fibroblasts). Trace amounts of this intermediate were also detected in chloroquine-treated cells. Combined activity assay and radioimmunoassay of cell lysates indicated that this partially processed form of cathepsin D possessed proteolytic activity. Whereas low medium concentrations of leupeptin (10-100 microM) but not E 64 appeared to stimulate procathepsin D secretion, neither agent appeared to have a major effect on the rate of proenzyme secretion at doses required to inhibit proteolytic maturation (1-10 mM). Furthermore, pretreatment of cells with 10 mM leupeptin appeared only to delay, but not prevent, the intracellular transport of cathepsin D to lysosomes. In contrast, chloroquine increased procathepsin D secretion in a dose-dependent manner, diverting the majority of newly synthesized procathepsin D from the intracellular protease(s) responsible for proteolytic processing. These results suggest that cysteine proteases participate in the proteolytic maturation of procathepsin D during the transport of newly synthesized enzyme to lysosomes, but cysteine protease-mediated proteolytic processing is not required for cathepsin D activation or lysosomal translocation.
