BACKGROUND: In lipoid proteinosis (LP) vascular anomalies represent severe functional defects caused by excessive deposition of basement membrane (BM)-like matrix, particularly around small subepithelial blood vessels. OBJECTIVE: Correlation of microvascular anomalies in morphology and ultrastructure with extracellular matrix composition and cell interactions for elucidating vascular involvement in LP-pathophysiology. METHODS: Biopsies from non-related LP-patients were analyzed by indirect immunofluorescence (IIF), electron microscopy (EM), and immune-EM (ImEM). RESULTS: In LP-skin and mucosa the thickened vessel walls stained strongly for the BM-components type IV collagen, laminin, perlecan, and nidogen (IIF). Integrin alpha6beta4 was regularly collocated with endothelial surface markers such as PECAM (CD31). Ultrastructure (EM) revealed highly ordered matrix deposits around microvessels, with frequently collapsed lumina, functionally compensated by increased vascular density (histology, IIF). Pericytes were trapped between these concentric BM-layers at varying distances towards the periphery (EM), contrasting their regularly close endothelial apposition. Periodic type IV collagen patterns (ImEM) corroborated the multiple BM-leaflet structure and the lack of a common 'fused' endothelial-pericyte BM, seen normally. Presumptive secretory vesicles, abundant in both cell types, implied an equal contribution to BM-synthesis, but also indicated partial loss of endothelial polarity. CONCLUSIONS: In LP thickened vessel walls, composed of multiple BM, profoundly alter microvascular properties, also by interference with endothelial-pericyte interactions. The increased microvascular density reflects compensatory restoration for disabled function. Most remarkable was the exaggerated secretory activity (also at luminal surfaces) underlining the regulatory key role of extracellular matrix protein 1 (ECM1; mutated in LP) in export or turnover of all major BM-components.
BACKGROUND: In lipoid proteinosis (LP) vascular anomalies represent severe functional defects caused by excessive deposition of basement membrane (BM)-like matrix, particularly around small subepithelial blood vessels. OBJECTIVE: Correlation of microvascular anomalies in morphology and ultrastructure with extracellular matrix composition and cell interactions for elucidating vascular involvement in LP-pathophysiology. METHODS: Biopsies from non-related LP-patients were analyzed by indirect immunofluorescence (IIF), electron microscopy (EM), and immune-EM (ImEM). RESULTS: In LP-skin and mucosa the thickened vessel walls stained strongly for the BM-components type IV collagen, laminin, perlecan, and nidogen (IIF). Integrin alpha6beta4 was regularly collocated with endothelial surface markers such as PECAM (CD31). Ultrastructure (EM) revealed highly ordered matrix deposits around microvessels, with frequently collapsed lumina, functionally compensated by increased vascular density (histology, IIF). Pericytes were trapped between these concentric BM-layers at varying distances towards the periphery (EM), contrasting their regularly close endothelial apposition. Periodic type IV collagen patterns (ImEM) corroborated the multiple BM-leaflet structure and the lack of a common 'fused' endothelial-pericyte BM, seen normally. Presumptive secretory vesicles, abundant in both cell types, implied an equal contribution to BM-synthesis, but also indicated partial loss of endothelial polarity. CONCLUSIONS: In LP thickened vessel walls, composed of multiple BM, profoundly alter microvascular properties, also by interference with endothelial-pericyte interactions. The increased microvascular density reflects compensatory restoration for disabled function. Most remarkable was the exaggerated secretory activity (also at luminal surfaces) underlining the regulatory key role of extracellular matrix protein 1 (ECM1; mutated in LP) in export or turnover of all major BM-components.
Authors: Li Kong; Qingyun Tian; Fengjin Guo; Maria T Mucignat; Roberto Perris; Sandy Sercu; Joseph Merregaert; Paul E Di Cesare; Chuan-Ju Liu Journal: Matrix Biol Date: 2010-02-04 Impact factor: 11.583