Abstract-Experimental studies have shown that in hypertrophy and heart failure, accumulation of microtubules occurs that impedes sarcomere motion and contributes to decreased ventricular compliance. We tested the hypothesis that these changes are present in the failing human heart and that an entire complex of structural components, including cytoskeletal, linkage, and extracellular proteins, are involved in causing functional deterioration. In explanted human hearts failing because of dilated cardiomyopathy (ejection fraction Յ20%), expression of ␣-and -tubulin, desmin, vinculin, fibronectin, and vimentin was determined by Northern and Western blot analysis and compared with normal myocardium from explants not used for transplantation. The mRNA for ␣-and -tubulin was increased to 2.
The cytoskeleton of cardiac myocytes consists of actin, the intermediate filament desmin and of alpha- and beta-tubulin that form the microtubules by polymerization. Vinculin, talin, dystrophin and spectrin represent a separate group of membrane-associated proteins. In numerous experimental studies, the role of cytoskeletal alterations especially of microtubules and desmin, in cardiac hypertrophy and failure (CHF) has been described. Microtubules were found to be accumulated thereby posing an increased load on myocytes which impedes sarcomere motion and promotes cardiac dysfunction. Other groups were unable to confirm microtubular densification. The possibility exists that these changes are species, load and chamber dependent. Recently, damage of the dystrophin molecule and MLP (muscle LIM protein) were identified as possible causes of CHF. Our own studies in human hearts with chronic CHF due to dilated cardiomyopathy (DCM) showed that a morphological basis of reduced contractile function exists: the cytoskeletal and membrane-associated proteins are disorganized and increased in amount confirming experimental reports. In contrast, the contractile myofilaments and the proteins of the sarcomeric skeleton including titin, alpha-actinin, and myomesin are significantly decreased. These changes can be assumed to occur in stages and are here presented as a testable hypothesis: (1) The early and reversible stage as present in animal experiments is characterized by accumulation of cytoskeletal proteins to counteract an increased strain without loss of contractile material. (2) Further accumulation of microtubules and desmin to compensate for the increasing loss of myofilaments and titin represents the late clinical and irreversible state. We suggest, based on a structural basis for heart failure, an integrative view which closes the gap between changes within cardiac myocytes and the involvement of the extracellular matrix, including the development of fibrosis. These factors contribute significantly to structural ventricular remodeling and dilatation finally resulting in reduced cardiac function.
We investigated the paracrine effect of cardiac microvascular endothelial cells (MVEC) on cultured adult rat cardiomyocytes (ARC). ARC were exposed for 8 days to serum-free medium (CM) conditioned by MVEC. Controls were grown in FCS or FCS-free medium. Protein synthesis of CM-stimulated ARC increased twofold versus 5% FCS-stimulated cells until day 8. Seventy-nine percent of CM-treated myocytes survived, whereas only twenty-four percent of FCS-free ARC retained viability. The phenotype of myocytes exposed to CM was different from control. Analysis by confocal laser microscopy of CM-stimulated myocytes showed actin staining throughout the whole cell body up to the peripheral extensions, with concomitant appearance of myomesin in a cross-striated pattern. The reexpression of fetal α-smooth muscle actin determined immunohistochemically and by Western blot increased from day 6 in CM-treated cells, whereas ARC grown in up to 20% serum were negative. These effects could not be mimicked by any of the other cardioactive substances tested here, indicating a novel trophic factor in CM.
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