Differentiation of Pericytes in Culture Is Accompanied by Changes in the Extracellular Matrix

We have previously reported that pericytes derived from retinal and brain microvessels aggregate into nodules soon after reaching confluence. Nodule formation involves a reorganization of the cells resulting in the presence of sparse cells, confluent monolayers, multilayers, sprouts, and nodules wit...

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Bibliographic Details
Published in:In Vitro Cellular & Developmental Biology - Animal 1991-08, Vol.27A (8), p.651-659
Main Authors: A. M. Schor, A. E. Canfield, P. Sloan, Schor, S. L.
Format: Article
Language:English
Subjects:
Animals
Biological and medical sciences
Blotting, Northern
brain
Cattle
cell culture
Cell Differentiation
Cell physiology
Cells, Cultured
Chondrocytes
collagen
Collagen - analysis
Collagen - biosynthesis
Collagens
Cultured cells
differentiation
DNA Probes
Endothelial cells
expression
Extracellular matrix
Extracellular Matrix - physiology
Fluorescent Antibody Technique
Fundamental and applied biological sciences. Psychology
Gels
laminin
Laminin - analysis
Laminin - genetics
Microvessels
Molecular and cellular biology
Nodules
pericytes
Proline - metabolism
retina
Retinal Vessels - cytology
Retinal Vessels - physiology
RNA - genetics
RNA - isolation & purification
Sprouts
tissue culture
Ungulates
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Summary:We have previously reported that pericytes derived from retinal and brain microvessels aggregate into nodules soon after reaching confluence. Nodule formation involves a reorganization of the cells resulting in the presence of sparse cells, confluent monolayers, multilayers, sprouts, and nodules within the same culture dish. Extracellular calcification occurs only within the nodules, demonstrating that pericytes are capable of undergoing osteogenic differentiation in culture and that this differentiation is related to nodule formation. Using immunofluorescence we have now studied the distribution of laminin, type IV collagen, type X collagen, and tenascin in pericyte cultures during nodule formation. These matrix macromolecules were also identified by a combination of biochemical techniques, including Northern blot hybridization, immunoblotting and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A molecule that seems to be related to type X collagen was demonstrated by the presence of a pepsin-resistant, collagenase-sensitive polypeptide of molecular weight approximately 45 kDa. The production of laminin, type X-related collagen, and tenascin by pericytes has not been previously reported. Our results suggest that the synthesis or distribution or both of these molecules is dependent on the state of pericyte differentiation. The expression of laminin, type IV collagen, and type X-related collagen was maximal in multilayer areas, sprouts, and nodules. Tenascin appeared homogeneously distributed in monolayer and multilayer areas; when calcified nodules were present, the anti-tenascin serum preferentially decorated a discrete area circumscribing the nodules. Tenascin and type X collagen have been found transiently in vivo preceding calcification; their possible role in this process is not known. Our results also suggest an association between laminin, type IV collagen, and calcification. The in vitro experimental system described here may help to clarify the role of matrix macromolecules in the calcification process.
ISSN:0883-8364
2327-431X
1543-706X
DOI:10.1007/bf02631109