We have established that treatment of cultured human skin fibroblasts with tropoelastin or with heterogenic peptides, obtained after organo-alkaline or leukocyte elastase hydrolysis of insoluble elastin, induces a high expression of pro-collagenase-1 (pro-matrix metalloproteinase-1 (pro-MMP-1)). The identical effect was achieved after stimulation with a VGVAPG synthetic peptide, reflecting the elastin-derived domain known to bind to the 67-kDa elastin-binding protein. This clearly indicated involvement of this receptor in the described phenomenon. This notion was further reinforced by the fact that elastin peptides-dependent MMP-1 up-regulation has not been demonstrated in cultures preincubated with 1 mM lactose, which causes shedding of the elastin-binding protein and with pertussis toxin, which blocks the elastin-binding protein-dependent signaling pathway involving G protein, phospholipase C, and protein kinase C. Moreover, we demonstrated that diverse peptides maintaining GXXPG sequences can also induce similar cellular effects as a "principal" VGVAPG ligand of the elastin receptor. Results of our biophysical studies suggest that this peculiar consensus sequence stabilizes a type VIII -turn in several similar, but not identical, peptides that maintain a sufficient conformation to be recognized by the elastin receptor. We have also established that GXXPG elastin-derived peptides, in addition to pro-MMP-1, cause up-regulation of pro-matrix metalloproteinase-3 (pro-stromelysin 1). Furthermore, we found that the presence of plasmin in the culture medium activated these MMP proenzymes, leading to a consequent degradation of collagen substrate. Our results may be, therefore, relevant to pathobiology of inflammation, in which elastin-derived peptides bearing the GXXPG conformation (created after leukocyte-dependent proteolysis) bind to the elastin receptor of local fibroblasts and trigger signals leading to expression and activation of MMP-1 and MMP-3, which in turn exacerbate local connective tissue damage.The extracellular matrix protein elastin is responsible for the elastic properties of tissues such as lung, skin, and large arteries (1-3). Due to its numerous cross-links and the extreme hydrophobicity of its tropoelastin chains, elastin is highly resistant to proteolysis. However, during inflammatory disorders, proteinases secreted from polymorphonuclear neutrophils, such as elastase, cathepsin G, and gelatinase B may cause significant elastolysis (4).It has been established that peptides derived from elastin or from the hydrophobic domains of tropoelastin interact with cells via a cell surface-resided 67-kDa elastin-binding protein identical to an enzymatically inactive, alternatively spliced form of -galactosidase (5). The binding of elastin peptides to the elastin-binding protein (EBP) 1 has been shown to be responsible for chemotaxis to the peptides (6 -12), stimulation of cell proliferation (13-16), ions flux modifications (17, 18), vasorelaxation (19 -22), and enzymes secretion (23,24).Matrix metall...
Cardiovascular diseases (CVDs) are the leading cause of death worldwide and represent a major problem of public health. Over the years, life expectancy has considerably increased throughout the world, and the prevalence of CVD is inevitably rising with the growing ageing of the population. The normal process of ageing is associated with progressive deterioration in structure and function of the vasculature, commonly called vascular ageing. At the vascular level, extracellular matrix (ECM) ageing leads to molecular alterations in long half-life proteins, such as elastin and collagen, and have critical effects on vascular diseases. This review highlights ECM alterations occurring during vascular ageing with a specific focus on elastin fragmentation and also the contribution of elastin-derived peptides (EDP) in age-related vascular complications. Moreover, current and new pharmacological strategies aiming at minimizing elastin degradation, EDP generation, and associated biological effects are discussed. These strategies may be of major relevance for preventing and/or delaying vascular ageing and its complications.
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Aging is a progressive process determined by genetic and acquired factors. Among the latter are the chemical reactions referred to as nonenzymatic posttranslational modifications (NEPTMs), such as glycoxidation, which are responsible for protein molecular aging. Carbamylation is a more recently described NEPTM that is caused by the nonenzymatic binding of isocyanate derived from urea dissociation or myeloperoxidase-mediated catabolism of thiocyanate to free amino groups of proteins. This modification is considered an adverse reaction, because it induces alterations of protein and cell properties. It has been shown that carbamylated proteins increase in plasma and tissues during chronic kidney disease and are associated with deleterious clinical outcomes, but nothing is known to date about tissue protein carbamylation during aging. To address this issue, we evaluated homocitrulline rate, the most characteristic carbamylation-derived product (CDP), over time in skin of mammalian species with different life expectancies. Our results show that carbamylation occurs throughout the whole lifespan and leads to tissue accumulation of carbamylated proteins. Because of their remarkably long half-life, matrix proteins, like type I collagen and elastin, are preferential targets. Interestingly, the accumulation rate of CDPs is inversely correlated with longevity, suggesting the occurrence of still unidentified protective mechanisms. In addition, homocitrulline accumulates more intensely than carboxymethyl-lysine, one of the major advanced glycation end products, suggesting the prominent role of carbamylation over glycoxidation reactions in age-related tissue alterations. Thus, protein carbamylation may be considered a hallmark of aging in mammalian species that may significantly contribute in the structural and functional tissue damages encountered during aging.
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...
Elastin is the macromolecular polymer of tropoelastin molecules responsible for the elastic properties of tissues. The understanding of its specific elasticity is uncertain because its structure is still unknown. Here, we report the first experimental quantitative determination of bovine elastin secondary structures as well as those of its corresponding soluble -elastin. Using circular dichroism and Fourier transform infrared and near infrared Fourier transform Raman spectroscopic data, we estimated the secondary structure contents of elastin to be ϳ10% ␣-helices, ϳ45% -sheets, and ϳ45% undefined conformations. These values were very close to those we had previously determined for the free monomeric tropoelastin molecule, suggesting thus that elastin would be constituted of a closely packed assembly of globular  structural class tropoelastin molecules crosslinked to form the elastic network (liquid drop model of elastin architecture). The presence of a strong hydration shell is demonstrated for elastin, and its possible contribution to elasticity is discussed.
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