Showing papers on "Smoothelin published in 1999"

Cultured Porcine Coronary Artery Smooth Muscle Cells: A New Model With Advanced Differentiation

Abstract: Arterial intimal thickening after endothelial injury induced in rodents has proven to be a relatively unreliable model of restenosis for testing clinically useful compounds. The same has been found for cultured rat or rabbit vascular smooth muscle cells (SMCs). To test alternative possibilities, we have studied several differentiation features of porcine coronary artery SMCs, cultured up to the 5th passage after enzymatic digestion of the media. The effects of heparin, transforming growth factor (TGF)-beta1 or TGF-beta2, and all-trans-retinoic acid (tRA) on proliferation, migration, and differentiation of these cells also were examined. Porcine arterial SMCs in culture not only express high levels of alpha-smooth muscle (SM) actin but, contrary to rodent SMCs, also maintain an appreciable expression of SM myosin heavy chain isoforms 1 and 2, desmin, and smoothelin, a recently described late differentiation marker of vascular SMCs. We demonstrate for the first time that smoothelin is colocalized with alpha-SM actin in these cells. Finally, we show that in the porcine model, heparin is more potent than TGF-beta1 or TGF-beta2 and tRA in terms of inhibition of proliferation and migration and of increasing the expression of differentiation markers. This model should be a useful complement to in vivo studies of SMC differentiation and of pathological situations such as restenosis and atheromatosis.

A novel isoform of the smooth muscle cell differentiation marker smoothelin.

Abstract: Studies on smooth muscle cell differentiation and those on vascular development in mouse and humans have long been hampered by the lack of suitable markers. Here we describe a novel, large isoform of smoothelin, a structural protein of differentiated, contractile smooth muscle cells. The protein, which is highly conserved in mouse and humans, shows homology with other cytoskeleton-associated smooth muscle cell proteins and contains an actinin-type actin-binding domain. Northern blot analysis from various mouse organs identified short and long smoothelin mRNA forms, which exhibit distinct tissue expression patterns. The short form is highly expressed in visceral muscle tissues such as intestine and stomach and is not detectable in brain, while the long mRNA form is expressed in all vascularized organs. These results may provide new tools and approaches to study both smooth muscle cell differentiation and proliferative vascular disease.

A novel isoform of the smooth muscle cell differentiation marker

Abstract: Studies on smooth muscle cell differentiation and those on vascular development in mouse and humans have long been hampered by the lack of suitable markers. Here we describe a novel, large isoform of smoothelin, a structural protein of differentiated, contractile smooth muscle cells. The protein, which is highly conserved in mouse and humans, shows homology with other cytoskele- ton-associated smooth muscle cell proteins and contains an actinin-type actin-binding domain. Northern blot analy- sis from various mouse organs identified short and long smoothelin mRNA forms, which exhibit distinct tissue ex- pression patterns. The short form is highly expressed in visceral muscle tissues such as intestine and stomach and is not detectable in brain, while the long mRNA form is expressed in all vascularized organs. These results may provide new tools and approaches to study both smooth muscle cell differentiation and proliferative vascular dis- ease.

Smoothelin in adult and developing human arteries and myocardium.

Abstract: The aim of this investigation was to study, with immunohistochemical methods, the distribution of the novel cytoskeletal protein smoothelin in human cardiovascular tissues, the possible changes during the development of the cardiovascular system and its correlation to the intermediate filament proteins desmin and vimentin. Smoothelin was detected in smooth muscle cells of the fetal coronary arteries. In very young subjects (up to 3 months of age), only a few cells in the media of the elastic arteries contained smoothelin, whereas it was present in most smooth muscle cells in the muscular arteries. In individuals older than 1 year, most smooth muscle cells in the media of all blood vessels contained smoothelin. In vessels with a developed intima, smoothelin was present in a variable proportion of the smooth muscle cells. With few exceptions, smoothelin was more frequently detected than desmin in medial smooth muscle cells. Smoothelin and vimentin were codistributed in the smooth muscle cells of the media in most vessels. In the cardiomyocytes (fetal to adult age), the smoothelin antibody detected epitopes located at the Z-disc level but not in the intercalated discs. In conclusion, smoothelin is more widely distributed in the muscular arteries than in the elastic arteries early in life, and thus exhibits a variable distribution during postnatal development of vascular tissues. In the adult, smoothelin is detected in the media of most vascular smooth muscle cells, both in muscular and elastic arteries, and is not necessarily codistributed with either desmin or vimentin. Evidence that smoothelin is present in human striated cardiomyocytes is also presented.

Smoothelin and intermediate filament proteins in human aortocoronary saphenous vein by-pass grafts.

Abstract: The aim of this immunohistochemical investigation was to study the distribution of the novel cytoskeletal protein smoothelin and the intermediate filament proteins vimentin and desmin in normal human great saphenous vein and in human aortocoronary by-pass vein grafts. Smoothelin was present in most smooth muscle cells in the media of the native vein. In the neointima of the vein grafts that had been in situ for three months or more, smoothelin was, in general, present only in few smooth muscle cells. Desmin was distributed in the same pattern as smoothelin in the native great saphenous vein. When desmin and smoothelin were present in the neointima, smoothelin was detected in more cells than desmin. Vimentin was present in most cells in all wall layers of both the native saphenous vein and the vein grafts. Vascular smooth muscle cells containing vimentin but not desmin or smoothelin are the principal cells in the neointima of human aortocoronary vein grafts. In some grafts, however, all three cytoskeletal proteins were detected in the neointima. The distribution of smoothelin and desmin in aortocoronary vein grafts support the postulate that these proteins are expressed mainly in the contractile smooth muscle cell phenotype.