Phenotypic changes in morphology and collagen polymorphism of cultured bovine and porcine aortic endothelium

Collagen Structure-Function Mapping Informs Applications for Regenerative Medicine

Type I collagen, the predominant protein of vertebrates, assembles into fibrils that orchestrate the form and function of bone, tendon, skin, and other tissues. Collagen plays roles in hemostasis, wound healing, angiogenesis, and biomineralization, and its dysfunction contributes to fibrosis, atherosclerosis, cancer metastasis, and brittle bone disease. To elucidate the type I collagen structure-function relationship, we constructed a type I collagen fibril interactome, including its functional sites and disease-associated mutations. When projected onto an X-ray diffraction model of the native collagen microfibril, data revealed a matrix interaction domain that assumes structural roles including collagen assembly, crosslinking, proteoglycan (PG) binding, and mineralization, and the cell interaction domain supporting dynamic aspects of collagen biology such as hemostasis, tissue remodeling, and cell adhesion. Our type III collagen interactome corroborates this model. We propose that in quiescent tissues, the fibril projects a structural face; however, tissue injury releases blood into the collagenous stroma, triggering exposure of the fibrils' cell and ligand binding sites crucial for tissue remodeling and regeneration. Applications of our research include discovery of anti-fibrotic antibodies and elucidating their interactions with collagen, and using insights from our angiogenesis studies and collagen structure-function model to inform the design of super-angiogenic collagens and collagen mimetics.

Angiogenesis in collagen I requires alpha2beta1 ligation of a GFP*GER sequence and possibly p38 MAPK activation and focal adhesion disassembly

Angiogenesis depends on proper collagen biosynthesis and cross-linking, and type I collagen is an ideal angiogenic scaffold, although its mechanism is unknown. We examined angiogenesis using an assay wherein confluent monolayers of human umbilical vein endothelial cells were overlain with collagen in a serum-free defined medium. Small spaces formed in the cell layer by 2 h, and cells formed net-like arrays by 6-8 h and capillary-like lumens by 24 h. Blocking of alpha2beta1, but not alpha1 or alpha(v)beta3 integrin function halted morphogenesis. We found that a triple-helical, homotrimeric peptide mimetic of a putative alpha2beta1 binding site: alpha1(I)496-507 GARGERGFP*GER (where single-letter amino acid nomenclature is used, P* = hydroxyproline) inhibited tube formation, whereas a peptide carrying another putative site: alpha1(I)127-138 GLP*GERGRP*GAP* or control peptides did not. A chemical inhibitor of p38 mitogen-activated protein kinase (p38 MAPK), SB202190, blocked tube formation, and p38 MAPK activity was increased in collagen-treated cultures, whereas targeting MAPK kinase (MEK), focal adhesion kinase (FAK), or phosphatidylinositol 3-kinase (PI3K) had little effect. Collagen-treated cells had fewer focal adhesions and 3- to 5-fold less activated FAK. Thus capillary morphogenesis requires endothelial alpha2beta1 integrin engagement of a single type I collagen integrin-binding site, possibly signaling via p38 MAPK and focal adhesion disassembly/FAK inactivation.

Heterogeneity in collagen biosynthesis by sprouting retinal endothelial cells

Bovine retinal microvascular endothelial cells can display two distinct and reversible morphologies in culture: 'cobblestone' and 'sprouting'. The cobblestone morphology resembles the resting cells lining the lumen of mature vessels while the sprouting morphology resembles the angiogenic cells involved in the formation of new vessels. Retinal cells displayed some heterogeneity in the shape of the cells making up the cobblestone monolayer. In contrast, all cell lines displayed an identical sprouting morphology. We have investigated the synthesis of matrix macromolecules by retinal endothelial cells displaying either the cobblestone or the sprouting morphology. Type IV was the only collagen synthesised by eight different lines of early-passage (between one and six) cobblestone endothelial cells. Collagen types I and III were not detected in these cultures. In contrast, heterogeneity was observed in the types of collagen synthesized by four lines of early-passage cells displaying the sprouting morphology. That is, two lines synthesised collagen types, II, III and IV, whereas two other lines continued to synthesise only type IV collagen. Both cobblestone and sprouting cells synthesised fibronectin and thrombospondin, although the relative amounts of these macromolecules varied with culture conditions. The pattern of collagen synthesis by cobblestone cells was also affected by in vitro "ageing": 4/5 lines examined above passage eight synthesised collagen types I, III and IV. Our results indicate that there is heterogeneity in the sprouting phenotype displayed by retinal endothelial cells, and that this phenotype is not necessarily associated with the synthesis of type I collagen. We suggest that differences in the spectrum of matrix macromolecules synthesised by sprouting endothelial cells may play a role in the control of angiogenesis.

Extracellular matrix gene expression by human endothelial and smooth muscle cells

In this study, the expression of extracellular matrix genes by vascular cells from human iliac blood vessels was characterized on the mRNA steady-state level by slot blot and Northern transfer analyses, as well as by in situ hybridization. Endothelial cells were isolated from adult human iliac arteries and veins, as well as from umbilical veins; smooth muscle cells were isolated from adult human iliac arteries and inferior vena cava. The results show that confluent umbilical vein endothelial cells expressed the genes that encode types I, III, IV and VI collagens, as well as fibronectin and laminin. In contrast, the iliac endothelial cells expressed the genes for types IV and V collagens, fibronectin and laminin; mRNA transcripts for types I, III and VI collagens were not detectable. The smooth muscle cells from iliac arteries or inferior vena cava displayed gene expression for types I, III, IV, V and VI collagens, fibronectin and laminin. The results indicate major differences in gene expression for the various types of collagens by human iliac endothelial and smooth muscle cells. Furthermore, the fetal-derived umbilical endothelial cells displayed differential collagen gene expression from that of adult iliac endothelial cells.

Progressive modulation of endothelial phenotype during in vitro blood vessel formation

"Sprouting" vascular endothelial cells were used as an in vitro model system to study the progressive morphologic and biosynthetic changes associated with the formation of tubular structures. In vitro, sprouting endothelial cells formed spontaneously without the addition of any exogenous factors from cultures of cloned endothelium exhibiting a polygonal/cobblestone phenotype. These phenotypically variant endothelial cells differentiated to form associated cell networks or nodules which gradually reorganized into tubular structures. Concomitant with these morphologic changes, the biosynthesis of extracellular matrix proteins was modulated, as determined by Northern blot analysis, metabolic labeling, and immunocytochemistry. The initial sprouting phase was characterized by the induction of type I collagen synthesis and the appearance of fibronectin containing the ED-A domain, in comparison to their absence in cloned cultures displaying a stable polygonal/cobblestone phenotype. The organizational stage, where the sprouting endothelial cells assembled into tubular structures, was additionally characterized by the expression of type IV collagen. These studies demonstrate that the progression from polygonal/cobblestone to sprouting cultures, and subsequent tubular organization, involves major alterations in extracellular matrix protein expression. This developmental phenomenon, although not completely analogous to blood vessel formation in vivo, nevertheless may be helpful in understanding the role of matrix macromolecules in the angiogenic process.

Formation of organoid structures and extracellular matrix production in an intestinal epithelial cell line during long-term in vitro culture

During the long-term in vitro maintenance of an epithelial cell line established from rat duodenum (IEC-17) we have observed progressive morphological changes which, after approximately 4-5 months in culture, led to a loss of substrate adherence and to the formation of organoid structures characterized by organized layers of cells separated by continuous extracellular-like material and delimiting close lumina. The cells exhibited a defined polarity with deposition of extracellular matrix components on one side and development of microvilli on the opposite surface. The morphological changes observed did not appear to be the expression of spontaneous transformation since the cells retained a normal diploid rat karyotype and did not grow in soft agar. In this report we present the optical and electron microscopical characterization of the progressive organotypic differentiation of the cell line. Further studies are currently in progress to characterize the extracellular matrix during the process of differentiation.

The biosynthesis of extracellular-matrix components by bovine retinal endothelial cells displaying distinctive morphological phenotypes

Previous studies have indicated that the morphology and behaviour of bovine retinal microvessel endothelial cells are influenced by culture conditions in vitro. Data are presented here concerning the biosynthesis of matrix macromolecules by bovine retinal endothelial cells cultured under conditions in which the cells display either the 'cobblestone' or the 'sprouting' phenotype. Newly synthesized matrix proteins were identified by their characteristic electrophoretic mobilities, immunoprecipitation with specific antibodies, susceptibilities to enzymic digestions and chromatographic behaviour. Type IV procollagen was the major collagenous species synthesized by early-passage cells forming a 'cobblestone' monolayer. In contrast, cells displaying the 'sprouting' morphology switched to the predominant synthesis of interstitial fibrillar collagens (types I and III). Fibronectin was synthesized by retinal endothelial cells under all the experimental conditions studied. A non-collagenous glycoprotein of Mr approx. 47,000 was also a major biosynthetic product of these cells. The synthesis of thrombospondin was very much dependent on the nature of the substratum on which the cells were cultured. This glycoprotein was synthesized in large amounts by 'cobblestone' endothelial cells cultured on gelatin-coated dishes, whereas its synthesis was markedly decreased by culturing the cells on collagen gels, and the protein appeared to be absent when the cells were plated within collagen gels ('sprouting' cells). Late-passage retinal cells synthesized predominantly type I procollagen, variable amounts of type III procollagen and only traces of type IV procollagen, irrespective of whether the cells displayed a 'cobblestone' or 'sprouting' morphology.

Biochemical and ultrastructural study of the effects of proline analogues on collagen synthesis in 3T6 fibroblasts

The effects of proline analogues, L-3,4-dehydroproline and L-azetidine-2-carboxylic acid, on collagen synthesis by cultured 3T6 fibroblasts have been studied. Prolyl hydroxylase activity was partially inhibited in cells cultured with dehydroproline for 24 h, resulting in the synthesis of collagen in which the proline was underhydroxylated. Azetidine had no effect on prolyl hydroxylase and less effect on the degree of hydroxylation of proline. Fibroblasts grown in the presence of either analogue and fixed in-situ contained greatly distended cisternae of the rough endoplasmic reticulum. Proline analogues otherwise caused few ultrastructural changes in the cells. Treated cells which had been handled more roughly during preparation for electron microscopy contained many large cytoplasmic vacuoles in addition to dilated cisternae. Our results indicate that the major effect of the proline analogues was the inhibition of prolyl hydroxylation. However, electron microscopy of the treated cells revealed hitherto unreported cytoplasmic damage.