Cell contact as an independent factor modulating cardiac myocyte hypertrophy and survival in long-term primary culture.

Cardiac myocytes maintained in cell culture develop hypertrophy both in response to mechanical loading as well as to receptor-mediated signaling mechanisms. However, it has been shown that the hypertrophic response to these stimuli may be modulated through effects of intercellular contact achieved by maintaining cells at different plating densities. In this study, we show that the myocyte plating density affects not only the hypertrophic response and features of the differentiated phenotype of isolated adult myocytes, but also plays a significant role influencing myocyte survival in vitro. The native rod-shaped phenotype of freshly isolated adult myocytes persists in an environment which minimizes myocyte attachment and spreading on the substratum. However, these conditions are not optimal for long-term maintenance of cultured adult cardiac myocytes. Conditions which promote myocyte attachment and spreading on the substratum, on the other hand, also promote the re-establishment of new intercellular contacts between myocytes. These contacts appear to play a significant role in the development of spontaneous activity, which enhances the redevelopment of highly differentiated contractile, junctional, and sarcoplasmic reticulum structures in the cultured adult cardiomyocyte. Although it has previously been shown that adult cardiac myocytes are typically quiescent in culture, the addition of beta-adrenergic agonists stimulates beating and myocyte hypertrophy, and thereby serves to increase the level of intercellular contact as well. However, in densely-plated cultures with intrinsically high levels of intercellular contact, spontaneous contractile activity develops without the addition of beta-adrenergic agonists. In this study, we compare the function, morphology, and natural history of adult feline cardiomyocytes which have been maintained in cultures with different levels of intercellular contact, with and without the addition of beta-adrenergic agonists. Intercellular contact, communication, and transmission of contractile forces between myocytes appears to play a primary role in remodeling the 2-dimensional cell layer into a parallel alignment of elongated myocytes with highly developed intercalated disk-like junctions. This highly differentiated state is very stable, and cultures which achieve this state exhibit significantly greater longevity than more sparsely plated myocytes. These myocytes typically continue beating, and survive from 6 to more than 12 weeks in culture. When this level of contact and differentiation are not achieved, even among beta-adrenergic stimulated myocytes, contractile activity is not sustained, myofibrils atrophy, there is little or no development of junctional complexes, and the period of myocyte viability is typically no more than 5 weeks in vitro.

Some growth factors stimulate cultured adult rabbit ventricular myocyte hypertrophy in the absence of mechanical loading.

Cultured adult rabbit cardiac myocytes treated with recombinant growth factors display enhanced rates of protein accumulation (ie, growth) in response to insulin and insulin-like growth factors (IGFs), but epidermal growth factor, acidic or basic fibroblast growth factor, and platelet-derived growth factor failed to increase contractile protein synthesis or growth of the heart cells. Insulin and IGF-1 increased growth rates by stimulating anabolic while simultaneously inhibiting catabolic pathways, whereas IGF-2 elevated growth modestly by apparently inhibiting lysosomal proteolysis. Neutralizing antibodies directed against either IGF-1 or IGF-2 or IGF binding protein 3 blocked protein accumulation. A monoclonal antibody directed against the IGF-1 receptor also inhibited changes in protein turnover provoked by recombinant human IGF-1 but not IGF-2. Of the other growth factors tested, only transforming growth factor-beta 1 increased the fractional rate of myosin heavy chain (MHC) synthesis, with beta-MHC synthesis being elevated and alpha-MHC synthesis being suppressed. However, the other growth factors were able to modestly stimulate the rate of DNA synthesis in this preparation. Bromodeoxyuridine labeling revealed that these growth factors increased DNA synthesis in myocytes and nonmyocytes alike, but the heart cells displayed neither karyokinesis or cytokinesis. In contrast, cocultures of cardiac myocytes and nonmyocytes and nonmyocyte-conditioned culture medium failed to enhance the rate of cardiac MHC synthesis or its accumulation, implying that quiescent heart cells do not respond to "conditioning" by cardiac nonmyocytes. These findings demonstrated that insulin and the IGFs promote passively loaded cultured adult rabbit heart cells to hypertrophy but suggest that other growth factors tested may be limited in this regard.

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.

Morphometric evaluation of the contractile apparatus in primary cultures of rabbit cardiac myocytes.

Rabbit cardiac myocytes remain quiescent for more than 1 month when cultured at low density. During this period, myofibrillar volume density declines sixfold as myofibrils are disassembled or degraded and are replaced by actin and alpha-actinin-positive, myosin-negative structures that resemble myofibrils but lack thick filaments. Such structures are termed minute myofibrils. The length of the sarcomeres in these altered myofibrils is significantly less than length values obtained from freshly isolated heart cells or from contracting myocytes. A number of high density cultures develop spontaneous, synchronous contraction during the second week of culture. Myofibrillar volume density is stabilized when beating begins, and no further decline is observed in the succeeding weeks of culture. Such contracting myocytes display myofibrils typical of normal heart with no visible evidence of minute myofibrils. The volume density of the transverse tubular system also declines significantly in both beating and nonbeating myocytes, and its reduction appears more closely correlated with cell spreading than with beating per se. No quantitative changes in volume density of mitochondria or sarcoplasmic reticulum could be documented, but the structural organization of the sarcoplasmic reticulum seems to be greatly influenced by the physiological state of the heart cell. The present observations document the importance of mechanical factors in regulating the integrity of the contractile apparatus in cardiac myocytes and emphasize the utility of the cultured heart cell to directly investigate structure-function relations in individual myocytes.

Cell shape and organization of the contractile apparatus in cultured adult cardiac myocytes.

The isolation and culture of adult cardiac myocytes has proved to be an ideal model system to explore myocardial biology at the cellular level. A major criticism of this model, however, has been that organ-specific characteristics such as cell shape and subcellular structural organization cannot be retained in vitro for prolonged periods of time. Encasing freshly isolated myocytes in a matrix of calcium alginate enables one to maintain the rod-like, three-dimensional (3D) shape of the cultured myocyte. Such preparations more closely resemble their in vivo counterparts with respect to the organization of the contractile apparatus, the transverse tubular system and the sarcoplasmic reticulum than do heart cells cultured on a two-dimensional (2D) plastic surface. Stereologic measurements reveal that myofibrillar volume density (VvMYF) decreases in both non-beating preparations over a 2-week interval, but VvMYF is conserved in cells cultured in an alginate matrix when compared to those myocytes maintained on a laminin-coated substratum. The present observations suggest that in the absence of contractile function myofibrillar atrophy appears responsible for the decline in VvMYF in alginate (3D) preparations, whereas atrophy and subcellular remodelling probably mediate the myofibrillar loss and reorganization that develops when adult heart cells are cultured on a 2D surface.