Effects of static or dynamic mechanical stresses on osteoblast phenotype expression in three‐dimensional contractile collagen gels

Studies performed at tissular (three‐dimensional, 3‐D) or cellular (two‐dimensional, 2‐D) levels showed that the loading pattern plays a crucial role in the osteoblastic physiology. In this study, we attempted to investigate the response of a 3‐D osteoblastic culture submitted to either no external stress or static or dynamic stresses. Rat osteosarcoma cells (ROS 17/2.8) were embedded within collagen type I lattices and studied for 3 weeks. Entrapment and proliferation of cells within the hydrated collagen gel resulted in the generation of contractile forces, which led to contraction of the collagen gel. We used this ability to evaluate the influence of three modes of mechanical stresses on the cell proliferation and differentiation: (1) the freely retracted gels (FRG) were floating in the medium, (2) the tense gels (TG) were stretched statically and isometrically, with contraction prevented in the longitudinal axis, and (3) the dynamic gels (DG) were floating gels submitted to periodic stresses (50 or 25 rpm frequency). Gels showed maximum contraction at day 12 in 50 rpm DG, followed by 25 rpm DG, then FRG (88%, 81%, 70%, respectively) and at day 16 in TG (33%). The proliferation rate was greater in TG than in FRG (+52%) but remained low in both DGs. Gel dimensions were related to the collagen concentration and on a minor extent to cell number. Cells in DG appeared rounder and larger than in other conditions. In TG, cells were elongated and oriented primarily along the tension axis. Scanning electron microscopy (SEM) showed that tension exerted by cells in TG led to reorientation of collagen fibers which, in turn, determined the spatial orientation and morphology of the cells. Transmission electron microscopy (TEM) performed at maximum proliferation showed a vast majority of cells with a distended well‐developed RER filled with granular material and numerous mitochondria. Alkaline phosphatase activity peaked close to the proliferation peak in FRG, whereas in TG, a biphasic curve was observed with a small peak at day 4 and the main peak at day 16. In DG, this activity was lower than in the two other conditions. A similar time course was observed for alkaline phosphatase gene expression as assessed by Northern blots. Regardless of the conditions, osteocalcin level showed a triphasic pattern: a first increase at day 2, followed by a decrease from day 4 to 14, and a second increase above initial values at day 18. Microanalysis‐x indicated that mineralization occurred after 14 days and TEM showed crystals within the matrix. We showed that static and dynamic mechanical stresses, in concert with 3‐D collagen matrices, played a significant role on the phenotypic modulation of osteoblast‐like cells. This experimental model provided a tool to investigate the significance and the mechanisms of mechanical activity of the 3‐D cultured osteoblast‐like cells. J. Cell. Biochem. 76:217–230, 1999. © 1999 Wiley‐Liss, Inc.

[1]  S. Rodan,et al.  Parathyroid hormone-responsive clonal cell lines from rat osteosarcoma. , 1980, Endocrinology.

[2]  G. Stein,et al.  The onset and progression of osteoblast differentiation is functionally related to cellular proliferation. , 1989, Connective tissue research.

[3]  D. Hartmann,et al.  Ultrastructural and immunocytochemical study of bone-derived cells cultured in three-dimensional matrices: influence of chondroitin-4 sulfate on mineralization. , 1990, Differentiation; research in biological diversity.

[4]  M. M. Bradford A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. , 1976, Analytical biochemistry.

[5]  M. Nagayama,et al.  In vitro mineralization of osteoblastic cells derived from human bone. , 1990, Bone and mineral.

[6]  A Guignandon,et al.  Demonstration of feasibility of automated osteoblastic line culture in space flight. , 1997, Bone.

[7]  M. Lafage-Proust,et al.  Effects of gravitational changes on the bone system in vitro and in vivo. , 1998, Bone.

[8]  P. Chomczyński,et al.  Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. , 1987, Analytical biochemistry.

[9]  Y Usson,et al.  Effects of intermittent or continuous gravitational stresses on cell-matrix adhesion: quantitative analysis of focal contacts in osteoblastic ROS 17/2.8 cells. , 1997, Experimental cell research.

[10]  M. Beckerle,et al.  Interaction of plasma membrane fibronectin receptor with talin—a transmembrane linkage , 1986, Nature.

[11]  S. Goldstein,et al.  Bone cell culture in a three‐dimensional polymer bead stabilizes the differentiated phenotype and provides evidence that osteoblastic cells synthesize type III collagen and fibronectin , 1991, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[12]  S. Wientroub,et al.  Bone marrow‐derived stromal cell line expressing osteoblastic phenotype in vitro and osteogenic capacity in vivo , 1989, Journal of cellular physiology.

[13]  G. Stein,et al.  Osteocalcin gene promoter: Unlocking the secrets for regulation of osteoblast growth and differentiation , 1998, Journal of cellular biochemistry.

[14]  Anne Caillot-Augusseau,et al.  L'ostéocalcine: Un marqueur de la formation osseuse Aspects méthodologiques , 1996 .

[15]  A Heinonen,et al.  Bone mineral density in female athletes representing sports with different loading characteristics of the skeleton. , 1995, Bone.

[16]  S. Milam,et al.  Cells transmit spatial information by orienting collagen fibers. , 1989, Matrix.

[17]  J. Heino,et al.  Transforming Growth Factor- Regulates Collagen Gel Contraction by Increasing 21 Integrin Expression in Osteogenic Cells (*) , 1995, The Journal of Biological Chemistry.

[18]  E. Bonucci Comments on the ultrastructural morphology of the calcification process: an attempt to reconcile matrix vesicles, collagen fibrils, and crystal ghosts. , 1992, Bone and mineral.

[19]  H. Stegemann [Microdetermination of hydroxyproline with chloramine-T and p-dimethylaminobenzaldehyde]. , 1958, Hoppe-Seyler's Zeitschrift fur physiologische Chemie.

[20]  G. Stein,et al.  The influence of type I collagen on the development and maintenance of the osteoblast phenotype in primary and passaged rat calvarial osteoblasts: modification of expression of genes supporting cell growth, adhesion, and extracellular matrix mineralization. , 1995, Experimental cell research.

[21]  B. Trump,et al.  Cell death and the disease process. The role of calcium , 1981 .

[22]  J. Aubin,et al.  Contraction and organization of collagen gels by cells cultured from periodontal ligament, gingiva and bone suggest functional differences between cell types. , 1981, Journal of cell science.