Abstract-The proteoglycan versican is one of several extracellular matrix (ECM) molecules that accumulate in lesions of atherosclerosis and restenosis. Its unique structural features create a highly interactive molecule that binds growth factors, enzymes, lipoproteins, and a variety of other ECM components to influence fundamental events involved in vascular disease. Versican is one of the principal genes that is upregulated after vascular injury and is a prominent component in stented and nonstented restenotic lesions. The synthesis of versican is highly regulated by specific growth factors and cytokines and the principal source of versican is the smooth muscle cell. Versican interacts with hyaluronan, a long chain glycosaminoglycan, to create expanded viscoelastic pericellular matrices that are required for arterial smooth muscle cell (ASMC) proliferation and migration. Versican is also prominent in advanced lesions of atherosclerosis, at the borders of lipid-filled necrotic cores as well as at the plaque-thrombus interface, suggesting roles in lipid accumulation, inflammation, and thrombosis. Versican influences the assembly of ECM and controls elastic fiber fibrillogenesis, which is of fundamental importance in ECM remodeling during vascular disease. Collectively, these studies highlight the critical importance of this specific ECM component in atherosclerosis and restenosis. Key Words: proteoglycans Ⅲ versican Ⅲ extracellular matrix Ⅲ atherosclerosis Ⅲ smooth muscle cells V ersican is a chondroitin sulfate proteoglycan (CSPG) that is present in the extracellular matrix (ECM) of normal blood vessels and increases dramatically in all forms of vascular disease. 1,2 A number of reports within the last few years have documented a significant involvement of versican in lesions of atherosclerosis and restenosis and these observations, coupled to those that demonstrate that this ECM proteoglycan regulates many of the events that contribute to the formation of atherosclerotic and restenotic lesions, highlights the critical importance of versican in the pathogenesis of vascular disease.Versican is one of many proteoglycans identified in vascular tissue or synthesized by vascular cells 3 and together with biglycan, decorin, and perlecan constitute the bulk of the proteoglycans found in the interstitial space. 2 Versican interacts with hyaluronan, a long chain high molecular weight glycosaminoglycan (GAG), that is also present in the extracellular matrix (ECM) of blood vessels and increases as versican in vascular disease. 4 The versican gene and protein follow a domain template. The amino-terminal globular domain (G1) binds hyaluronan, and the carboxy-terminal globular domain (G3) resembles the selectin family of proteins, consisting of a C-type lectin adjacent to two epidermal growth factor (EGF) domains and a complement regulatory region. The middle region of the versican core protein is encoded by two large exons that specify the chondroitin sulfate attachment regions of versican (Figure 1). These highly interactiv...
Versican is an extracellular matrix (ECM) proteoglycan that interacts with cells by binding to non-integrin and integrin receptors and to other ECM components that associate with the cell surface. Recent studies have shown also that versican interacts with myeloid and lymphoid cells promoting their adhesion and production of inflammatory cytokines. Versican is produced by stromal cells, as well as leukocytes, and is markedly increased in inflammation. Inflammatory agonists, such as double-stranded RNA mimetics (e.g., poly I:C), stimulate stromal cells, such as smooth muscle cells and fibroblasts, to produce fibrillar ECMs enriched in versican and hyaluronan (HA) that interact with leukocytes promoting their adhesion. Interference with the incorporation of versican into this ECM blocks monocyte adhesion and dampens the inflammatory response. Tumor cells also express elevated levels of versican which interact with myeloid cells to promote an inflammatory response, through stimulating cytokine release, and metastasis. In addition, myeloid cells, such as macrophages in tumors, synthesize versican which affects tumor cell phenotypes, inflammation, and subsequent metastasis. Versican, by binding to hyaluronan, influences T lymphocyte phenotypes and in part controls the ability of these cells to synthesize and secrete cytokines that influence the immune response. Collectively, these studies indicate that versican as an ECM molecule plays a central role in inflammation and as a result it is emerging as a potential target promising wide therapeutic benefits.
Background Versican is an extracellular matrix (ECM) proteoglycan that is present in the pericellular environment of most tissues and increases in many different diseases. Versican interacts with cells to influence the ability of cells to proliferate, migrate, adhere and assemble an ECM. Scope of Review The structure of the versican molecule is briefly reviewed and studies highlighting those factors that promote versican synthesis and degradation and their impact on cell phenotype in disease are discussed. Particular attention is given to vascular disease, but other diseases where versican is important are covered as well, most notably different forms of cancers. Attention is given to mechanisms(s) by which versican influences cell behaviors through either direct or indirect processes. Versican produced by either stromal cells or myeloid cells can have a major impact influencing immunity and inflammation. Finally, studies controlling versican accumulation that either delay or inhibit the progression of disease will be highlighted. Major Conclusions Versican is one component of the ECM that can influence the ability of cells to proliferate, migrate, adhere, and remodel the ECM. Targeting versican as a way to control cell phenotype offers a novel approach in the treatment of disease. Significance ECM molecules such as versican contribute to the structural integrity of tissues and interact with cells through direct and indirect means to regulate, in part, cellular events that form the basis of disease.
Small airways are the major site of airflow obstruction in chronic obstructive pulmonary disease (COPD). This is attributed to loss of elastin in alveoli and fibrosis in small airways. In the present study, it was hypothesised that changes to elastic fibres in alveoli might be paralleled by a similar reduction in elastic fibres in small airways.Tissue blocks from patients who had lobectomy for bronchial carcinoma were studied. Patients were classified as COPD (forced expiratory volume in one second (FEV1) ,80% predicted, FEV1/ forced vital capacity (FVC) ,0.7) or controls (FEV1 o80% pred, FEV1/FVC o0.7). Elastic fibres were visualised using Elastic van Gieson staining and the volume fraction (v/f) of elastic fibres was determined as a percentage of tissue volume using point counting. Elastic fibre networks were also visualised by confocal microscopy.The v/f for elastic fibres in alveoli was 18.6% for COPD and 32.8% in controls. In the airways the v/f was 14.6% for COPD and 25.5% in controls. FEV1% predicted was correlated with v/f in both alveoli and small airways.The volume fraction of elastic fibres was reduced to a similar extent in small airways and alveoli in chronic obstructive pulmonary disease and both were correlated with the extent of airflow obstruction. Loss of elastic fibres in small airways may contribute to the development of airflow obstruction in chronic obstructive pulmonary disease.
Versican is an extracellular matrix proteoglycan produced by many cells. Although versican is generally known as a large chondroitin sulfate proteoglycan (CSPG), the smallest splice variant, V3, consists only of the amino- and carboxy-terminal globular domains and is therefore predicted to be a small glycoprotein, lacking CS chains. The large size, negative charge, and ability of versican variants to form pericellular coats with hyaluronan are responsible for many of its effects. V3, lacking the large size and high charge density, but retaining the hyaluronan-binding domain of the larger isoforms, may have different effects on cell phenotype. To determine whether V3 alters cell phenotype, Fisher rat arterial smooth muscle cells (ASMCs), which express the larger CSPG versican splice forms (V0 and V1) were retrovirally transduced with the rat V3 cDNA. Northern analysis for versican RNAs confirmed that cells transduced with V3 retrovirus, but not cells tranduced with the empty vector, expressed RNA of the size expected for V3/neo(r) bicistronic RNA. V3 overexpressing cells were more spread on tissue culture plastic, had a smaller length-to-breadth ratio and were more resistant to release from the culture dish by trypsin. Interference reflection microscopy of sparsely plated cells showed larger areas of close contact between the V3 expressing cells and the coverslip, in comparison to control cells. Focal contacts in the periphery of V3 expressing cells were larger. Growth and migration studies revealed that V3 transduced cells grow slower and migrate a shorter distance in a scratch wound assay. The increased adhesion and the inhibition of migration and proliferation resulting from V3 overexpression are the opposites of the known and predicted effects of the other variants of versican. V3 may exert these effects through changes in pericellular coat formation, either by competing with larger isoforms for hyaluronan-binding, or by altering other components of the pericellular matrix.
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