Abstract
Left ventricular hypertrophy (LVH) is a secondary adaptation to increased external load. Various qualitative and quantitative changes in myocytes and extracellular components occur during the development of LVH. It has recently been demonstrated that α-smooth muscle actin (α-SMA)-expressing myofibroblasts appear in the interstitium of the heart subjected to increased workload suggesting that cardiac fibroblasts as well as myocytes alter their phenotype in response to pressure overload. In the present study, to explore the load-induced response and phenotypic modulation of cardiac fibroblasts, the localization of embryonic smooth muscle myosin heavy chain (SMemb) and α-SMA in thoracic aorta-constricted rat hearts was investigated by immunohistochemistry, and the morphology of the SMemb-expressing cells was examined by electron microscopy. In addition, to clarify the mechanisms by which SMemb is induced in pressure-overloaded hearts, mRNA expression of SMemb in aorta-constricted rat hearts and in transforming growth factor-β1 (TGF-β1)-treated or mechanically-stretched cultured cardiac fibroblasts was investigated. Enhanced staining of SMemb and α-SMA was detected in the interstitial spindle-shaped cells in the fibrotic lesions of the pressure-overloaded left ventricles by immunohistochemistry. These cells were demonstrated by electron microscopy to have features specific for activated fibroblasts such as serrated nuclei or prominent rough endoplasmic reticulum. These cells also had characteristic features of myofibroblasts, i.e. irregularly arranged actin filaments and scattered dense bodies. Northern blot analysis revealed increased mRNA levels of SMemb both in aorta-constricted rat hearts and in cultured cardiac fibroblasts stimulated by TGF-β1 or by mechanical stretch. These results suggest that SMemb may be a molecular marker both for the detection of activated cardiac fibroblasts that may play important roles in the remodeling of pressure-overloaded cardiac interstitium, and for the identification of the regulatory mechanisms that control the phenotypic modulation of cardiac fibroblasts in response to pressure overload.
