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Abstract
Lysyl oxidases (LOXs) are a family of copper-dependent oxido-deaminases that can modify the side chain of lysyl residues in collagen and elastin, thereby leading to the spontaneous formation of non-reducible aldehyde-derived interpolypeptide chain cross-links. The consequences of LOX inhibition in producing lathyrism are well documented, but the consequences on collagen fibril formation are less clear. Here we used β-aminoproprionitrile (BAPN) to inhibit LOX in tendon-like constructs (prepared from human tenocytes), which are an experimental model of cell-mediated collagen fibril formation. The improvement in structure and strength seen with time in control constructs was absent in constructs treated with BAPN. As expected, BAPN inhibited the formation of aldimine-derived cross-links in collagen, and the constructs were mechanically weak. However, an unexpected finding was that BAPN treatment led to structurally abnormal collagen fibrils with irregular profiles and widely dispersed diameters. Of special interest, the abnormal fibril profiles resembled those seen in some Ehlers-Danlos Syndrome phenotypes. Importantly, the total collagen content developed normally, and there was no difference in COL1A1 gene expression. Collagen type V, decorin, fibromodulin, and tenascin-X proteins were unaffected by the cross-link inhibition, suggesting that LOX regulates fibrillogenesis independently of these molecules. Collectively, the data show the importance of LOX for the mechanical development of early collagenous tissues and that LOX is essential for correct collagen fibril shape formation.
Highlights
Lysyl oxidase catalyzes collagen cross-link formation, which is essential for mechanically strong collagen fibrils
The stress/strain curve resulted in a tensile modulus of 2.59 MPa (Ϯ0.68) after 14 days and was increased to 12.38 MPa (Ϯ2.90) after 21 days in controls, whereas BAPNtreated constructs did not show any development over 7 days and had a value of 2.48 MPa (Ϯ0.46) after 21 days (Fig. 2D)
The present findings show that this holds true for in vitro engineered tendon constructs from adult human tendon fibroblasts that present aligned collagen fibrils
Summary
Lysyl oxidase catalyzes collagen cross-link formation, which is essential for mechanically strong collagen fibrils. Results: LOX inhibition stops early mechanical development of tendon constructs and leads to irregularly shaped collagen fibrils. Conclusion: Collagen cross-linking is essential for successful fibrillogenesis and regulates fibril shape. We used -aminoproprionitrile (BAPN) to inhibit LOX in tendon-like constructs (prepared from human tenocytes), which are an experimental model of cell-mediated collagen fibril formation. BAPN inhibited the formation of aldimine-derived cross-links in collagen, and the constructs were mechanically weak. An unexpected finding was that BAPN treatment led to structurally abnormal collagen fibrils with irregular profiles and widely dispersed diameters. Collagen type V, decorin, fibromodulin, and tenascin-X proteins were unaffected by the cross-link inhibition, suggesting that LOX regulates fibrillogenesis independently of these molecules. The data show the importance of LOX for the mechanical development of early
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