Hypoxia downregulates tropoelastin gene expression in rat lung fibroblasts by pretranslational mechanisms.

Elastolytic lung injury disrupts cell barriers, flooding alveoli and producing regional hypoxia. Abnormal O2 tensions may alter repair of damaged elastin fibers. To determine the effect of hypoxia on extravascular elastin formation, we isolated rat lung fibroblasts and cultured them under a variety of O2 conditions. Hypoxia downregulated tropoelastin mRNA in a dose- and time-related fashion while upregulating glyceraldehyde-3-phosphate dehydrogenase mRNA levels. The changes in tropoelastin gene expression were not due to cell toxicity as measured by chromium release and cell proliferation studies. Neither cycloheximide nor actinomycin D abrogated this effect. Hypoxia induced early decreases in tropoelastin mRNA stability; minor suppression of gene transcription occurred later. When returned to 21% O2, tropoelastin mRNA recovered to control levels in part by upregulating tropoelastin gene transcription. Taken together, these data indicate that hypoxia regulates tropoelastin gene expression and may alter repair of acutely injured lung.

Effect of okadaic acid on elastin gene expression in interstitial lung fibroblasts.

Okadaic acid (OA), a specific serine/threonine protein phosphatase inhibitor, downregulated tropoelastin formation and elastin mRNA levels in a dose-related and cycloheximide-sensitive fashion in cultured lung fibroblasts. Treatment with a tyrosine phosphatase inhibitor at high concentrations did not alter elastin mRNA levels, however. Nuclear run-on analysis indicated that OA primarily suppressed elastin gene expression through a transcriptional mechanism. In contrast to its effects on elastin expression, OA downregulated alpha 1(I) mRNA to significantly lesser degrees. The mechanism by which OA decreased elastin mRNA levels did not appear to involve protein kinase C or share the signaling pathway of IL-1 beta. Prolonged treatment with phorbol ester promoted the inhibitory effects of OA on elastin, as did shorter treatment with IL-1 beta. Moreover, transient transfection studies indicated that OA and IL-1 beta do not act through the same cis-acting element in the elastin promoter. Finally, unlike the transient effects of IL-1 beta, OA induced persistent inhibition of elastin expression by a transcriptional mechanism. Taken together, these data indicate that serine/threonine protein phosphorylation can regulate the amount and composition of extracellular matrix secreted by fibroblasts into the interstitium of the lung.