Lung fibroblast clones from normal and fibrotic subjects differ in hyaluronan and decorin production and rate of proliferation.

Development of fibrosis involves an increase in the deposition of connective tissue components including collagens, fibronectin and proteoglycans. One hypothesis to account for matrix deposition in fibrosis is that fibroblast with differing matrix producing capacity are involved in the fibrotic process. To test this hypothesis, primary fibroblast cultures and clones derived from these primary lines were established from the lung tissue of control patients and patients with pulmonary fibrosis. The primary lines and derived clones were studied in relation to their capacity to proliferate and to produce proteoglycans and hyaluronan. Primary fibroblast cultures and clones from normal subjects and patients with lung fibrosis differed considerably, with up to 13-fold difference, in both hyaluronan and proteoglycan production. The major proteoglycan produced was decorin in both controls and cultures from fibrotic patients, while cultures from patients with lung fibrosis had a higher expression of mRNA for both collagen and decorin. Clones derived from a primary line from a fibrotic patient secreted 3-fold greater amounts of decorin than those from a control subject. Furthermore, a negative correlation between proliferation and synthesis of decorin was noted. We suggest that different fibroblast clones accumulate in the lung, and that specific cell populations of high decorin producing fibroblasts may exist which are crucial in the pathogenesis of fibrosis.

Transforming growth factor-beta 1 specifically induce proteins involved in the myofibroblast contractile apparatus.

Transforming growth factor-beta(1) (TGF-beta(1)) induces alpha-smooth muscle actin (alpha-SMA) and collagen synthesis in fibroblast both in vivo and in vitro and plays a significant role in tissue repair and the development of fibrosis. During these processes the fibroblasts differentiate into activated fibroblasts (so called myofibroblasts), characterized by increased alpha-SMA expression. Because TGF-beta(1) is considered the main inducer of the myofibroblast phenotype and cytoskeletal changes accompany this differentiation, the main objective of this investigation was to study how TGF-beta(1) alters protein expression of cytoskeletal-associated proteins. Metabolic labeling of cell cultures by [(35)S]methionine, followed by protein separation on two-dimensional gel electrophoresis, displayed approximately 2500 proteins in the pI interval of 3-10. Treatment of TGF-beta(1) led to specific spot pattern changes that were identified by mass spectrometry and represent specific induction of several members of the contractile apparatus such as calgizzarin, cofilin, and profilin. These proteins have not previously been shown to be regulated by TGF-beta(1), and the functional role of these proteins is to participate in the depolymerization and stabilization of the microfilaments. These results show that TGF-beta(1) induces not only alpha-SMA but a whole set of actin-associated proteins that may contribute to the increased contractile properties of the myofibroblast. These proteins accompany the induced expression of alpha-SMA and may participate in the formation of stress fibers, cell contractility, and cell spreading characterizing the myofibroblasts phenotype.

Myofibroblast accumulation correlates with the formation of fibrotic tissue in a rat air pouch model.

OBJECTIVE: The pathogenesis of arthritic joints involves cartilage degradation and pannus formation. It is well known that pannus influences the cartilage; however, the mechanism behind how the degrading cartilage interacts with pannus is not well known. To investigate this interplay, the expression of extracellular matrix (ECM) components in pannus and the degrading cartilage was analyzed. METHODS: Studies were performed using a rat air pouch model where cotton with viable or killed cartilage was implanted into 7-day-old pouches for 1-28 days. The remodeling of cartilage and the formation of tissue in the cotton was characterized histologically by quantitation of infiltrated cells. The amounts of collagen, hyaluronan, and proteoglycan were estimated. RESULTS: Implantation of homologous femoral head cartilage in cotton resulted in extensive remodeling of cartilage and formation of ECM in the cotton. In cotton without cartilage, fibroblasts and myofibroblasts were the predominant cells in the early stage of analyses. The ECM formed in cotton was of a fibrotic type, with mainly collagen and smaller amounts of proteoglycans correlating to the presence of myofibroblasts. In the cotton with cartilage, however, inflammatory cells such as neutrophils, macrophages, and lymphocytes dominated. Delayed accumulation of collagen and increased synthesis of proteoglycans occurred early in cotton with viable as well as non-viable cartilage. In later stages, the cell pattern changed and the myofibroblasts emerged together with an increasing collagen formation. CONCLUSION: The interaction between cartilage and the newly formed granulation tissue results in a faster degradation of cartilage molecules, which in turn leak into the surrounding ECM and affect the recruitment of myofibroblasts. This indicates the importance of the micromatrix.