We have generated mice with targeted inactivation of the Plod1 gene for lysyl hydroxylase 1 (LH1). Its human mutations cause Ehlers-Danlos syndrome VIA (EDS VIA) characterized by muscular hypotonia, joint laxity, and kyphoscoliosis. The Plod1 ؊/؊ mice are flaccid and have gait abnormalities. About 15% of them died because of aortic rupture and smooth muscle cells in non-ruptured Plod1 ؊/؊ aortas showed degenerative changes. Collagen fibrils in the Plod1 ؊/؊ aorta and skin had an abnormal morphology. The LH activity level in the Plod1 ؊/؊ skin and aorta samples was 35-45% of that in the wild type. The hydroxylysine content was decreased in all the Plod1 ؊/؊ tissues, ranging from 22% of that in the wild type in the skin to 75 and 86% in the femur and lung. The hydroxylysylpyridinoline crosslinks likewise showed decreases in all the Plod1 ؊/؊ tissues, ranging from 28 and 33% of that in the wild type in the aorta and cornea to 47 and 59% in femur and tendon, while lysylpyridinolines were increased. The hydroxylysines found in the Plod1 ؊/؊ collagens and their cross-links were evidently synthesized by the other two LH isoenzymes. Few data are available on abnormalities in EDS VIA tissues other than the skin. Plod1 ؊/؊ mice offer an in vivo model for systematic analysis of the tissue-specific consequences of the lack of LH1 activity and may also provide a tool for analyzing the roles of connective tissue in muscle function and the complex interactions occurring in the proper assembly of the extracellular matrix.Lysyl hydroxylase (LH, 2 EC 1.14.11.4) catalyzes the hydroxylation of lysine residues mainly but not exclusively in -X-LysGly-triplets in collagens and proteins with collagen-like sequences (1). The enzyme resides within the endoplasmic reticulum and has three human and mouse isoenzymes, LHs 1-3 (1-7). The hydroxylysine residues formed have two important functions: they are essential for the stability of the intermolecular cross-links that provide the collagen fibrils with their tensile strength and mechanical stability, and they serve as attachment sites for carbohydrate units, either the monosaccharide galactose or the disaccharide glucosylgalactose (1). Collagen cross-link formation occurs in the extracellular matrix and is initiated by the conversion of specific lysine or hydroxylysine residues in the telopeptides, i.e. the short non-triple helical ends of collagen molecules, into the aldehydes allysine or hydroxyallysine, respectively, catalyzed by lysyl oxidase (8). The telopeptides are connected with the triple helical part of an adjacent molecule by difunctional immature cross-links in the characteristic staggered array of collagen molecules in a fibril. The three main fibril-forming collagens, types I, II, and III, have four cross-linking sites, one in each telopeptide and two in the triple helical region, close to its N-and C-terminal ends (9). If the residue in the telopeptide is hydroxyallysine, the difunctional cross-links can mature into trifunctional non-reducible cross-links comprising lysylpyri...
Bruck syndrome is a rare autosomal recessive connective tissue disorder characterized by fragile bones, joint contractures, scoliosis, and osteoporosis. The telopeptides of bone collagen I are underhydroxylated in these patients, leading to abnormal collagen cross-linking. Three point mutations in lysyl hydroxylase (LH) 2, the enzyme responsible for the hydroxylation of collagen telopeptides, have been identified in Bruck syndrome. As none of them affects the residues known to be critical for LH activity, we studied their consequences at the molecular level by analyzing the folding and catalytic properties of the corresponding mutant recombinant polypeptides. Folding and oligomerization of the R594H and G597V mutants were abnormal, and their activity was reduced by >95% relative to the wild type. The T604I mutation did not affect the folding properties, although the mutant retained only ϳ8% activity under standard assay conditions. As the reduced activity was caused by a 10-fold increase in the K m for 2-oxoglutarate, the mutation interferes with binding of this cosubstrate. In the presence of a saturating 2-oxoglutarate concentration, the activity of the T604I mutant was ϳ30% of that of the wild type. However, the T604I mutant did not generate detectable amounts of hydroxylysine in the N-terminal telopeptide of a recombinant procollagen I chain when coexpressed in insect cells. The low activity of the mutant LH2 polypeptides is in accordance with the markedly reduced extent of collagen telopeptide hydroxylation in Bruck syndrome, with consequent changes in the cross-linking of collagen fibrils and severe abnormalities in the skeletal structures.
Rupture of the collagenous, fibrous cap of an atherosclerotic plaque commonly causes thrombosis. Activated immune cells can secrete mediators that jeopardize the integrity of the fibrous cap. This study aimed to determine the relationship between T-cell-mediated inflammation and collagen turnover in a mouse model of experimental atherosclerosis. Both Apoe(-/-) x CD4dnTbetaRII mice with defective transforming growth factor-beta receptors in T cells (and hence released from tonic suppression of T-cell activation) and lesion size-matched Apoe(-/-) mice were used. Picrosirius red staining showed a lower content of thick mature collagen fibers in lesions of Apoe(-/-) x CD4dnTbetaRII mice, although both groups had similar levels of procollagen type I or III mRNA and total collagen content in lesions. Analysis of both gene expression and protein content showed a significant decrease of lysyl oxidase, the extracellular enzyme needed for collagen cross-linking, in aortas of Apoe(-/-)--CD4dnTbetaRII mice. T-cell-driven inflammation provoked a selective and limited increase in the expression of proteinases that catabolize the extracellular matrix. Atheromata of Apoe(-/-)--CD4dnTbetaRII mice had increased levels of matrix metalloproteinase-13 and cathepsin S mRNAs and of the active form of cathepsin S protein but no increase was detected in collagen fragmentation. Our results suggest that exaggerated T-cell-driven inflammation limits collagen maturation in the atherosclerotic plaque while having little effect on collagen degradation.
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