Evidence suggests that transforming growth factor beta (TGF-beta) may play a central role in a variety of fibroproliferative disorders via the induction of extracellular matrix accumulation. The three mammalian TGF-beta isoforms are present in the normal lung, but very little is known about their expression during lung injury and repair. To more fully understand the role of TGF-beta in lung repair, we investigated the expression of the TGF-beta 1, TGF-beta 2, and TGF-beta 3 isoforms in a bleomycin-induced model of pulmonary fibrosis using immunohistochemical and in situ hybridization techniques. We found expression of the three TGF-beta isoforms, in an identical pattern, widely distributed throughout the normal rat lung: in airways, blood vessels, lung parenchyma, and alveolar macrophages. In general, the distribution of TGF-beta mRNA and protein coincided; however, bronchial epithelial cells were a notable exception, exhibiting immunoreactivity but no mRNA expression. During the "inflammatory" phase (days 1 and 3) of bleomycin-induced injury there was an increase in the mRNA and protein expression of all three TGF-beta isoforms in the injured areas, most prominently in parenchymal cells and alveolar macrophages. There was a further increase in TGF-beta isoform expression in the areas of developing fibrosis during the later reparative phase (days 7 and 14), and the bronchial epithelium, previously not expressing TGF-beta mRNA, showed strong expression of mRNA for the three isoforms concomitant with increased immunoreactivity. These findings implicate the three mammalian TGF-beta isoforms in the dysregulated repair process that results in pulmonary fibrosis. Furthermore, the pattern of TGF-beta mRNA and protein expression by the bronchial epithelium suggests that a transition may occur at this site from a paracrine mode of action in the normal lung to an autocrine mode of action during the "reparative" phase of fibrosis.
Mesothelial cells play a critical role in the remodeling process that follows serosal injury. Although mesothelial cells are known to synthesize a variety of extracellular matrix components including types I, III, and IV collagens, their potential to participate in matrix degradation has not been explored. We now report that human pleural and peritoneal mesothelial cells express interstitial collagenase, 72-and 92-kD gelatinases (type IV collagenases), and the counterregulatory tissue inhibitor of metalloproteinases (TIMP). Our initial characterization of the mesothelial cell metalloenzymes and TIMP has revealed: (a) they are likely identical to corresponding molecules secreted by other human cells; (b) they are secreted rather than stored in an intracellular pool; (c) a primary site of regulation occurs at a pretranslational level; (d) phorbol myristate acetate, via activation of protein kinase C, upregulates expression of collagenase, 92-kD gelatinase, and TIMP, but has no effect on expression of 72-kD gelatinase; and (e) lipopolysaccharide fails to upregulate the biosynthesis of either metalloproteinases or TIMP. Of particular interest is the observation that the state of cellular differentiation has a striking influence on the expression of metalloenzymes and TIMP, such that epithelioid cells display a more matrix-degradative phenotype (increased 92-kD gelatinase and decreased TIMP) than their fibroblastoid counterparts. We speculate that mesothelial cells directly participate in the extracellular matrix turnover that follows serosal injury via elaboration of metalloproteinases and TIMP. Additionally, the reactive cuboidal mesothelium which is characteristic of the early response to serosal injury may manifest a matrix-degradative phenotype favoring normal repair rather than fibrosis. (J. Clin. Invest. 1993. 91:1792-1799
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