Differential inhibition of collagenase and interleukin-1alpha gene expression in cultured corneal fibroblasts by TGF-beta, dexamethasone, and retinoic acid.

PURPOSE: Expression of the genes for collagenase and interleukin-1alpha (IL-1alpha) are induced as stromal cells become activated to the repair fibroblast phenotype after injury to the cornea. This investigation examines the mechanisms whereby expression of these genes is inhibited by transforming growth factor-beta (TGF-beta), dexamethasone (DEX), or retinoic acid (RET A). METHODS: A model of freshly isolated cultures of corneal stromal cells and early passage cultures of corneal fibroblasts was used in these studies. This model reproduces the events of stromal cell activation in the corneal wound. RESULTS: In early passage cultures of corneal fibroblasts, expression of collagenase is under obligatory control by autocrine IL-1alpha. IL-1alpha controls its own expression through an autocrine feedback loop that is dependent on transcription factor NF-kappaB. TGF-beta, DEX, and RET A were each effective inhibitors of collagenase gene expression in these cells. Furthermore, these agents have the capacity to inhibit expression of IL-1alpha and this was correlated with their ability to affect DNA-binding activity of NF-kappaB. However, TGF-beta, DEX, and RET A were also effective inhibitors of the low level of collagenase expressed by freshly isolated corneal stromal cells that cannot express IL-1alpha. CONCLUSIONS: In cells with an active IL-1alpha autocrine loop there are at least two distinct signaling pathways by which collagenase gene expression can be modulated. The results of this study demonstrate that TGF-beta, DEX, and RET A differentially inhibit collagenase and IL-1alpha gene expression. This information will be useful in the design of therapeutic modalities for fibrotic disease in the cornea and other parts of the eye.

Regulation of gelatinase B production in corneal cells is independent of autocrine IL-1alpha.

PURPOSE: The matrix metalloproteinase gelatinase B is synthesized by cells at the leading edge of the corneal epithelium migrating to heal a wound. Recent data from the authors' laboratory suggest that excessive synthesis contributes to repair defects. The goal of the study reported here was to investigate mechanisms controlling gelatinase B production by corneal epithelial cells. METHODS: Freshly isolated cultures of corneal epithelial cells and early passage stromal fibroblasts from rabbit were used for these studies. RESULTS: In a previous study, it was found that the cytokine interleukin (IL)-1alpha is released into the culture medium of corneal epithelial cells more efficiently when they are plated at low density with limited cell-cell contact than when plated at high density. In this study, we show that production of gelatinase B by these cells is similarly affected by cell plating density. However, it is further demonstrated that these two events are not dependent on one another but occur in parallel: IL-1alpha does not regulate gelatinase B production (synthesis), nor was there evidence that any other secreted autocrine cytokine acts as mediator. Instead, our data suggest that gelatinase B production is downregulated directly by high cell density and indicate a connection to the level of protein kinase C activity. Nevertheless, the anticancer agent suramin, which blocks collagenase synthesis by interfering with autocrine cytokine-receptor interactions, still inhibits synthesis of gelatinase B. CONCLUSIONS: Unlike collagenase synthesis by corneal stromal fibroblasts, production (synthesis) of gelatinase B does not appear to be controlled by secreted autocrine cytokines but can still be inhibited by suramin. Suramin may make an effective therapeutic agent for controlling pathologic overproduction of gelatinase B in corneal ulcers.

Gelatinase B/lacZ transgenic mice, a model for mapping gelatinase B expression during developmental and injury-related tissue remodeling.

Matrix metalloproteinases (MMPs) drive normal tissue remodeling and are implicated in a wide range of pathologies. Although MMP activity is controlled at multiple levels, the primary regulation of MMP activity is transcriptional. The transcriptional promoter elements required for MMP gene expression in cultured cells have been defined, but this has not been extended to the in vivo situation. In this paper, we show that the DNA sequences between -522 and +19 of the rabbit gelatinase B gene (MMP-9) (as characterized in the transgenic mouse line 3445) constitute a minimal promoter that drives appropriate developmental and injury-induced reporter gene expression in transgenic mice. We further show that the expression and activity of three transcription factors (NF-kappaB, AP-2, and Sp1) that control the activity of the gelatinase B promoter are selectively induced in the epithelium migrating to heal a wound. Although promoter activity parallels expression of the endogenous gene in cell cultures, we show by several criteria that cell cultures cannot model many aspects of promoter regulation in vivo. This study reveals that the transgenic mouse line 3445 might be a useful model for investigating the regulation of gelatinase B expression in vivo and for identifying and characterizing new drugs that can control gelatinase B gene transcription.