Inducible adhesion of mesenchymal cells to elastic fibers: elastonectin.

Hornebeck, William; Tixier, J. M.; Robert, L.

doi:10.1073/pnas.83.15.5517

Cited by 84 publications

(39 citation statements)

References 18 publications

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“…We have reported that tropoelastin downregulates the induction of calcification via the elastin receptor (manuscript in submission), although the pathway of the inhibitory reaction by TE on calcification presents several candidate reactions such as the activation of signal transduction via the elastin receptor (33) and the binding of calcium by tropoelastin molecule (6,7). Moreover, it has been reported that TE has a variety of biological effects which are mediated by the elastin receptor, chemotactic cell migration, modulation of ion flux, adhesion of cells to elastin fibers, tumor cellmatrix interaction, elastase synthesis and release, free radical production, endothelium and nitric oxide-mediated vasorelaxation, chaperon for elastogenesis, lymphocyte proliferation, apoptotic cell death (34)(35)(36)(37)(38) as well as properties as a major elastic fiber component. In this study, we revealed a new candidate function of the TE molecule.…”

Section: Discussionmentioning

confidence: 99%

Characterization of an <i>in vitro</i> Model of Calcification in Retinal Pigmented Epithelial Cells

Sugitani

Wachi

Murata

et al. 2003

JAT

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Little is known about the relationship at the molecular and cellular levels between vascular calcification and elastic fibers essential for elasticity. To gain a better understanding of the physiological function of elastin in vascular calcification, we developed a calcification model on cultured bovine retinal-pigmented-epithelial cells (RPEs) that do not express endogenous tropoelastin. The addition of inorganic phosphate (NaH2PO4; Pi) induced calcium deposition in RPEs. The Pi-induced calcification, as assessed by the o-cresolphthalein complexone method, Goldenberg's method, and von Kossa staining, was completely inhibited by treatment with clodronate (DMDP) and phosphonoformic acid (PFA) and was weakly suppressed by treatment with levamisole. Moreover, the osteopontin mRNA expression was upregulated in the Pi-induced calcification of RPEs. These reactions in RPEs were characteristically consistent with those already established in cultured bovine aortic smooth muscle cells (BASMCs). Furthermore, bacterially expressed tropoelastin inhibited calcium deposition in RPEs as well as in BASMCs. Finally, Pi-induced calcification was partially suppressed after the addition of tropoelastin due to elastic fiber formation. In conclusion, we suggest that this calcification model in RPEs is useful for analyzing the relation between elastic fibers and vascular calcification, and that tropoelastin and elastic fibers may contribute to the inhibition of vascular calcification. J Atheroscler Thromb, 2003; 10: 48-56.

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Section: Discussionmentioning

confidence: 99%

Characterization of an <i>in vitro</i> Model of Calcification in Retinal Pigmented Epithelial Cells

Sugitani

Wachi

Murata

et al. 2003

JAT

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“…Elastin and fibrillin have been found to be present during the embryonic stages of heart development (Rosenquist et al, 1988;Gallagher et al, 1993). In addition, since elastin has been found to interact with neighboring cells by means of specific receptors (Hornebeck et al, 1986;Hinek et al, 1988), it may provide a structural link required for the generation of mechanical forces which are important during the morphogenesis of the heart.…”

Section: Introductionmentioning

confidence: 99%

Elastic extracellular matrix of the embryonic chick heart: An immunohistological study using laser confocal microscopy

Hurlé

Kitten

Sakai

et al. 1994

Developmental Dynamics

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The "elastic matrix" constitutes a specialized component of the extracellular matrix which confers resiliency to tissues and organs subjected to repeated deformations. The role of the elastic matrix in living organisms appears to be of key importance since diseases characterized by expression of defective inherited genes which encode components of the elastic matrix lead to premature death. While the elastic matrix of adult organs has received a great deal of attention, little is known about when it first appears in embryonic tissues or its possible role in developing organs. In the present study we have performed an immunohistochemical study of the distribution of elastin and three additional components often associated with elastic matrices in adult tissues (i.e., fibrillin, emilin, and type VI collagen) during the development of the chicken embryonic heart. The threedimensional arrangement of these components was established through the observation of wholemount specimens with scanning laser confocal microscopy. Our results revealed three different periods of heart development regarding the composition of the elastic matrix. Prior to stage 21 the embryonic heart lacks elastin but exhibits a matrix scaffold of fibrillin and emilin associated with the endocardium and the developing cardiac jelly. Between stages 22 and 29 the heart shows a transient elastic scaffold in the outflow tract which contains elastin, fibrillin, and emilin. Elastin-positive fibrillar material is also observed during these stages in the base of the atrioventricular cushion adjacent to the myocardial wall. In addition, emilin-positive material appears to be associated with the zones of formation of ventricular trabeculae. Collagen type VI was not detected during these early stages. From stage 30 to stage 40 a progressive modification of the pattern of distribution of elastin, fibrillin, emilin, and collagen type VI is observed in association with the formation of the definitive four-chambered heart. The distribution of the elastic scaffold in the outflow tract appears to be rearranged and becomes restricted to the roots of the main arteries. Each of the components studied here is also deposited at increasing levels in the developing valvular appa-ratus including the valve leaflets and the chordae tendinea. The components are also present in the subendocardial space where they form aligned fibrillar tracts, an arrangement suggestive of a role in ventricular contractile function. The epicardium constitutes an additional region of elastic matrix deposition during these later stages and contains elastic, fibrillin, and collagen type VI. Finally, during the later stages the intramyocardial matrix (''myocardial interstitium") is formed and characterized by an abundance of collagen type VI, emilin, and fibrillin but lacks elastin-positive material. This study suggests that during cardiac development there is not a fixed composition of the so-called "elastic matrix.'' Rather, combinations of the different components of the elastic matrice...

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“…41 Hornebeck et al 41 propose that the loss of the cell-elastin interaction leads to the modulation of the contractile to the synthetic phenotype of SMCs characteristic of the atherosclerotic vessel. To what degree this and other extracellular matrix components, such as proteoglycans organized in the type I collagen lattice, 742 may regulate biosynthetic activity by direct interaction or by influ- encing the effect of various growth factors 4344 remains to be elucidated.…”

Section: Discussionmentioning

confidence: 99%

Aortic smooth muscle cells in a three-dimensional collagen lattice culture. Evidence for posttranslational regulation of collagen synthesis.

Redecker-Beuke

Thie

Rauterberg

et al. 1993

Arterioscler Thromb

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Aortic smooth muscle cells were cultivated as monolayers on plastic or within collagen lattices with lowand high-serum supplementation, and the expression of mRNAs specific for pro alpha 1 (I) and pro alpha 1 (HI) collagen were studied by slot blot hybridization. The steady-state levels of pro alpha 1 (I) and pro alpha 1 (HI) collagen mRNA of cells within collagen lattices were found to be higher than those grown on plastic, although the production of collagen was lower. The degradation of pro alpha 1 (I) and pro alpha 1 (HI) collagen mRNAs as revealed in the presence of actinomycin D was not affected by culturing the cells within a collagen lattice. In vitro translation assays of mRNAs of monolayer-and lattice-cultured cells showed no differences in translatability. These data suggest the involvement of posttranslational control of collagen production in collagen lattice-cultured smooth muscle cells. (Arterioscler Thromb. 1993;13:1572-1579 KEY The collagens are known to be synthesized by smooth muscle cells (SMCs) present within the atheromatous plaque. However, the regulatory mechanisms involved in the synthesis of collagens by ill-coordinated cells are unknown. An important question still to be answered in relation to the possible role of collagens in atherogenesis is, therefore, how collagen synthesis of SMCs is regulated under normal and pathophysiological conditions.When healthy arterial SMCs are freed from their physiological matrix and are dispersed into monolayer culture on plastic, they begin to change their ultrastructural character. Cells show a modulation from the contractile state characteristic of the healthy vessel to the synthetic state typical of the atherosclerotic vessel, which is characterized by abundant rough endoplasmic reticulum and a large Golgi complex. When monolayer-cultured SMCs are reintegrated into a tissuelike matrix, ie, a three-dimensional network of type I collagen, SMCs reduce their collagen synthesis and suppress their responsiveness to soluble growth mediators.1112 To elucidate the mechanism responsible for the observed reduction of collagen production, we analyzed the molecular process involved in collagen biosynthesis of matrix-cultured cells. This article presents data concerning the level and the translational capacity of collagen mRNAs in SMCs grown within a type I collagen lattice with low-and high-serum supplementation. Our results showed that the steady-state levels of pro alpha 1 (I) and pro alpha 1 (III) collagen mRNA of SMCs decrease with increases in serum concentration. At each concentration tested, steadystate levels of mRNA in lattice-cultured SMCs were higher than those in monolayer-cultured cells. The elevated collagen mRNAs of lattice-cultured cells, however, were not paralleled by elevated collagen levels. The stabilities of pro alpha 1 (I) and pro alpha 1 (III) collagen mRNAs are not changed by culturing the SMCs within a collagen lattice. As the in vitro translation activity of mRNAs of lattice-cultured SMCs is not affected, it is concluded that control...

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Inducible adhesion of mesenchymal cells to elastic fibers: elastonectin.

Cited by 84 publications

References 18 publications

Characterization of an <i>in vitro</i> Model of Calcification in Retinal Pigmented Epithelial Cells

Characterization of an <i>in vitro</i> Model of Calcification in Retinal Pigmented Epithelial Cells

Elastic extracellular matrix of the embryonic chick heart: An immunohistological study using laser confocal microscopy

Aortic smooth muscle cells in a three-dimensional collagen lattice culture. Evidence for posttranslational regulation of collagen synthesis.

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