The binding of elastin peptides on the elastin receptor complex leads to the formation of intracellular signals but how this is achieved remains totally unknown. Using pharmacological inhibitors of the enzymatic activities of its subunits, we show here that the elastin peptide-driven ERK1/2 activation and subsequent pro-MMP-1 production, observed in skin fibroblasts when they are cultured in the presence of these peptides, rely on a membrane-bound sialidase activity. As lactose blocked this effect, the elastin receptor sialidase subunit, Neu-1, seemed to be involved. The use of a catalytically inactive form of Neu-1 and the small interfering RNA-mediated decrease of Neu-1 expression strongly support this view. Finally, we report that N-acetyl neuraminic acid can reproduce the effects of elastin peptides on both ERK1/2 activation and pro-MMP-1 production. Altogether, our results indicate that the enzymatic activity of the Neu-1 subunit of the elastin receptor complex is responsible for its signal transduction, presumably through sialic acid generation from undetermined substrates.Elastin is the extracellular matrix protein responsible for the elasticity of tissues. It is more abundant in tissues where resilience is required, such as skin, lung, ligaments, or large arteries (1). Elastin is constituted of tropoelastin molecules covalently bound to each other by covalent cross-links (2) and its hydrophobic and highly cross-linked nature make of it a very durable polymer experiencing essentially no turnover in healthy tissues (3).The biological role of elastin was originally thought to be restricted to this mechanical function. However, when Senior et al. (4) demonstrated that elastin digestion products were chemotactic for neutrophils and macrophages, it became suddenly apparent that peptides derived from amorphous elastin could modulate cell physiology. In fact, it has been shown because that fibroblasts (5-12), smooth muscle cells (7, 13-15), endothelial cells (16 -19), leukocytes (20, 21), and lymphocytes (22) were sensitive to the presence of these peptides yielding a broad range of biological activities (see Ref. 23 for a review). A corollary of these observations was that those cells do express a receptor for elastin peptides.The elastin receptor complex is constituted of three subunits, one peripheral 67-kDa subunit, which actually binds elastin, and two membrane-associated proteins of 61 and 55 kDa, respectively (10). The 67-kDa elastin-binding protein (EBP) 2 binds the VGVAPG elastin sequence with high affinity. Additionally, EBP can be eluted from elastin affinity column by galactosugars suggesting that the elastin-EBP interaction could be regulated by galactosugars bound on a lectin site on EBP (10, 24). Consequently, galactosugars such as lactose are commonly used antagonists of EBP.Later, the nature of this subunit was revealed by the work of Privitera et al. (25) who have shown that EBP is an enzymatically spliced variant of lysosomal -galactosidase (-Gal, EC 3.2.1.23). Consequently, it was hypot...
