Immunohistochemical analysis of the adaptation of adult guinea-pig cardiomyocytes in long-term cultures and in cocultures with cardiac neurons: a novel model for studies of myocardial function.

In this study, we used laser confocal scanning microscopy and immunofluorescent markers to describe the establishment of long-term cultures of adult guinea-pig cardiomyocytes and their cocultures with adult intrinsic cardiac neurons. We have also investigated the effect of plating density on the adaptation of the myocytes in culture. Providing that the preparation of freshly isolated cardiomyocytes consists mostly (> 80%) of rod-shaped, Ca-tolerant, and quiescent cells and these are plated under optimal conditions and density (10(5)/cm2), these myocytes have the following characteristics: (1) they remain elongated with regular ultrastructural characteristics and quiescent for several days; (2) within 10-14 days, they reestablish their intercellular contacts and resume contractile activity, which becomes synchronous all through the confluent layers; (3) they retain their regular myofibrilar striation all through the adaptation to culture conditions without any sign of dedifferentiation or redifferentiation; (4) these characteristics are lost when the cells are plated at too low (< 10(4)/cm2) or too high (2 x 10(5)/cm2) a density and they exhibit signs of dedifferentiation; (5) the adult ventricular myocytes appear to retain their ability to express atrial natriuretic peptide (ANP), as indicated by immunoreactivity to anti-ANP antibody; (6) this activity seems to be directly related to the surface area of the myocytes in contact with the substrate (i.e. to the 'stretch' of the myocytes); (7) the intrinsic cardiac neurons grow intricate networks of neurites, which form a free-ending type of contact with the cocultured myocytes. Long-term cultures of adult guinea-pig ventricular myocytes, alone or in their cocultures with cardiac neurons in which both are fully active functionally, provide a valuable experimental model which opens new possibilities for studying the cellular and molecular regulation of myocardial function under acute or chronic effects of various intrinsic and/or extrinsic factors, including neuroregulation.