Enhancement of tumorigenicity of human breast adenocarcinoma cells in nude mice by matrigel and fibroblasts.

The failure of MCF7 cells to induce the formation of tumours after sub-cutaneous inoculation into athymic nude mice can be obviated by the simultaneous injection of an extract of basement membrane proteins (matrigel). Tumour growth is promoted and the latency period is low (2 to 4 weeks). In the absence of matrigel, the simultaneous inoculation of fibroblasts and MCF7 cells also resulted in the development of tumours, but with a longer latency period (about 2 months). The tumorigenic synergy between matrigel and fibroblasts was evidenced by co-inoculating MCF7 cells MDA-MB 231 cells with fibroblasts and matrigel. This co-inoculation decreased the delay of appearance of the tumours and/or accelerated the tumour growth, depending upon the number of fibroblasts injected. Repeated injections of fibroblasts conditioned medium, at the site of inoculum of tumour cells also enhanced tumour growth, suggesting the involvement of soluble factors secreted by fibroblasts. Histologically, tumours induced by co-inoculation of tumour cells and fibroblasts contained more stromal structures including vimentin-positive cells, fibronectin and interstitial collagens. These data suggest that human tumours may be reconstituted and grown in athymic nude mice using basement membrane components and fibroblasts as inductors

The Classic: Bone Morphogenetic Protein

This Classic Article is a reprint of the original work by Marshall R. Urist and Basil S. Strates, Bone Morphogenetic Protein. An accompanying biographical sketch of Marshall R. Urist, MD is available at DOI 10.1007/s11999-009-1067-4; a second Classic Article is available at DOI 10.1007/s11999-009-1069-2; and a third Classic Article is available at DOI 10.1007/s11999-009-1070-9. The Classic Article is © 1971 by Sage Publications Inc. Journals and is reprinted with permission from Urist MR, Strates BS. Bone morphogenetic protein. J Dent Res. 1971;50:1392–1406

Increased Mrna Expression of Decorin in the Prolapsing Posterior Leaflet of the Mitral Valve

To improve our understanding of myxomatous degeneration of the valvar tissue as seen in mitral valve prolapse, we have compared the biosynthetic phenotype of the connective tissue cells in myxomatous segments (n=4) resected during surgery with that of homologous segments of normal valves (n=4) harvested in age-matched organ donors. The steady-state level of mRNA for selected extracellular matrix macromolecules and metalloproteinases was assessed by quantitative (internal standard controlled) reverse transcriptase-polymerase chain reaction (RT-PCR). Among the investigated gene products, the decorin mRNA expression was significantly increased in degenerative valve compared with normal tissue (211+/-48 vs. 100+/-70, p<0.02). The level of fibrillin 2 also tended to be increased (194+/-88 vs. 100+/-81, p=0.08). These results suggest that myxomatous valvar tissue is characterized by an overexpression of mRNA for decorin. Owing to the role of this small leucine-rich proteoglycan in the regulation of fibril assembly and stability, this alteration may account for or is a result of a defective organization of the collagen and elastic fibers in this disease and contribute to the intrinsic distensibility and fragility of the myxomatous tissue

Pronostic et prevention de l'atrophie blanche. [Prognosis and prevention of white atrophy]

White atrophy, defined by Milian, is a smooth ivory white plaque, slightly depressed, of variable dimensions, and surrounded by a pigmented telangiectasic area, several millimetres across. It is usually localised in the lower limbs and mostly affects middle-aged women. It is a symptom with multiple aetiopathology. It is to be bound in isolation, or forming part of the clinical picture of various affections caused by degeneration in the cutaneous vascularization. Sometimes it causes ulceration resistant to the available treatments. Some authors suggest an immunological pathology of vascular occlusion. Others consider that it is result of a localized disorder of coagulation or fibrinolysis

Mechanism of the growth and rupture of abdominal aortic aneurysm

The relationship between atherosclerosis and abdominal aortic aneurysm development is well known. Atherosclerosis cannot explain the whole mechanism. Genetic characters of mechanisms leading to abdominal aortic development is obvious from this study and others. Our study evidences an increased metalloproteases activity in aortic wall proportionally to the size of the abdominal aortic aneurysm. A decrease of aortic wall elastin is evidenced proportionally to the AAA size. Extractable collagen is significantly increased in the aortic wall of patients operated on for aortic rupture

Effect of Egf on Human Skin Fibroblasts Is Modulated by the Extracellular Matrix

The aim of this work was to clarify the reason why a discrepancy exists between the effects of epidermal growth factor (EGF) on fibroblasts in culture repressing collagen biosynthesis and in vivo stimulating wound healing. The effect of EGF on the biosynthetic activity of fibroblasts was measured in various conditions of cultures: on plastic, on plastic coated with various macromolecules of the extracellular matrix, on top of a type I collagen gel, and within a three-dimensional collagen lattice. While the noncollagen protein (NCP) synthesis was not affected by the interactions of the cell with the various coated matrices, collagen synthesis was inhibited. At the surface of a collagen gel, protein synthesis was reduced, while collagen synthesis and degradation were slightly stimulated. When embedded in a lattice, the overall biosynthetic activity of fibroblasts was largely depressed. The addition of EGF to cultures on plastic and on the various coated macromolecules resulted in a further repression of collagen synthesis while cell multiplication was slightly stimulated. On the contrary, the addition of EGF to fibroblasts in a collagen lattice resulted in a stimulation of both NCP and collagen synthesis as observed in vivo. These opposite effects of EGF in a two- or three-dimensional culture system are not related to modification in number or affinity of the EGF receptors at the cell surface. These results further support the similarity in the state of differentiation of fibroblasts in a three-dimensional lattice and in vivo

Development of a reconstituted nerve in a three-dimensional collagen gel under tension populated with fibroblasts and Schwann cells.

Our aim is to devise an artificially reconstituted nerve segment made of a three-dimensional collagen gel populated with aligned fibroblasts and Schwann cells. Collagen lattices were prepared by mixing concentrated medium, a type I collagen solution and rat Schwann cells (SC), rat neural fibroblasts (nF) or human dermal fibroblasts (dF) and allowed to polymerize at 37 degrees C. In these free-floating lattices, nF and dF retracted the gel more than SC. All cells appeared to be elongated and oriented at random. Rat cells obtained by enzymatic digestion of nerves undergoing wallerian degeneration retracted the gel at a larger extent than cells from intact nerves. Rectangular lattices restrained at each extremity acquired a paraboloid shape upon retraction by neural or dermal F reflecting the mechanical tension developed by these cells on their support. Adult SC alone produced a faint paraboloid even at high cell density while SC associated with nF developed a paraboloid similar to that obtained with nF alone. The mechanical force developed by dermal F and SC in the restrained lattice was measured by strain gauges and found much higher for F than for SC. In restrained lattices, both types of F were elongated and aligned to the long axis of the gel while SC elongated but not necessarily in a parallel fashion. The central portion of a mixed nF-SC collagen restrained lattice produces a flattened cylindric segment made of longitudinally oriented col-lagen fibrils, F and SC, which could represent a promising material for preparation of nerve grafts. An original plastic mould was devised to allow the preparation of cylindrical segments of free or restrained collagen lattices in view of in vitro and in vivo regeneration studies