Frog PNKT-4B cells express specific extracellular matrix-degrading enzymes and cytokines correlated with an invasive phenotype.

A temperature-dependent metastatic phenotype reported for a frog cell line, PNKT-4B, provided a means for studying potential mediators of cell-matrix interaction involved in metastatic invasion. Zymography revealed that these cells secreted enzyme species with properties and characteristics of mammalian metalloproteinases: collagenase, stromelysin, gelatinase A, and gelatinase B. These enzymes were produced by PNKT-4B cultures maintained at both invasive-permissive (28 degrees C), and invasion-restrictive (20 degrees C) temperatures. However, under the invasive-permissive culture condition cells produced more of the putative gelatinase B and A enzymes. In addition, an activated form of gelatinase A was produced only in invasion-permissive cultures. DNA synthesis bioassays (Mv1Lu cell line and mouse thymocytes) to detect growth promoting and/or inhibitory cytokines, revealed that PNKT-4B cultures kept at 28 degrees C released significantly higher levels of stimulatory (interleukin-1-like) and latent inhibitory (transforming growth factor-beta-like) substances into the medium compared to 20 degrees C cultures. Pre-absorption of media samples with heparin-sepharose indicated a second stimulatory cytokine as well. A corneal fibroblast bioassay that tests for mediators of collagenase synthesis, detected a stimulatory substance whose activity was greatly reduced in the presence of interleukin-1 receptor antagonist protein. Collagenase stimulatory activity present in 28 degrees C culture medium was significantly higher than equal samples from 20 degrees C cultures. These studies provide a molecular correlation between release of cytokines with properties of the metastatic phenotype seen in vivo. They further provide some of the first characterizations of frog MMPs and cytokines, which are likely to be involved in other tissue remodeling events.

Stromal fibroblasts synthesize collagenase and stromelysin during long-term tissue remodeling.

The process of connective tissue remodeling is an important mechanism contributing to tissue morphogenesis in development and homeostasis. Although it has long been known that remodeling tissues actively mediate collagenolysis, little is understood about the molecular mechanisms controlling this cell-regulated process. In this study, we examined the biosynthesis of collagenase and the related metalloproteinase, stromelysin, during remodeling of repair tissue deposited after mechanical injury to the rabbit cornea. Neither enzyme was synthesized by uninjured corneas; however, synthesis and secretion was detectable within one day after injury. Collagenase accumulated in its latent form while stromelysin appeared to be partially activated. Enzymes were synthesized by cells having a fibroblast phenotype. These cells were found within the stroma. New synthesis was correlated with accumulation of enzyme-specific mRNA. Highest levels of enzyme synthesis were observed in the repair tissue. However, stromal cells outside of the repairing area also synthesized both enzymes. The level of synthesis decreased in a gradient radiating from the repair tissue. Total synthetic levels in a given area of cornea were dependent on both the number of cells expressing enzyme and the rate of enzyme synthesis. Synthesis of collagenase was detected in repair tissue as long as nine months after injury. Our findings provide direct support for the hypothesis that new collagenase synthesis by cells in repair tissue is the first step in collagen degradation during long-term tissue remodeling.