ADAMTS expression and function in central nervous system injury and disorders

The components of the adult extracellular matrix in the central nervous system form a lattice-like structure that is deposited as perineuronal nets, around axon initial segments and as synapse-associated matrix. An abundant component of this matrix is the lecticans, chondroitin sulfate-bearing proteoglycans that are the major substrate for several members of the ADAMTSs (a disintegrin and metalloproteinase with thrombospondin motifs) family. Since lecticans are key regulators of neural plasticity, ADAMTS cleavage of lecticans would likely also contribute to neuroplasticity. Indeed, many studies have examined the neuroplastic contribution of the ADAMTSs to damage and recovery after injury and in central nervous system disease. Much of this data supports a role for the ADAMTSs in recovery and repair following spinal cord injury by stimulating axonal outgrowth after degradation of a glial scar and improving synaptic plasticity following seizure-induced neural damage in the brain. The action of the ADAMTSs in chronic diseases of the central nervous system appears to be more complex and less well-defined. Increasing evidence indicates that lecticans participate in synaptic plasticity in neurodegenerative disease states. It will be interesting to examine how ADAMTS expression and action would affect the progression of these diseases.     

Proteoglycans: key partners in bone cell biology

The diversity of bone proteoglycan (PG) structure and localisation (pericellular, extracellular in the organic bone matrix) reflects a broad spectrum of biological functions within a unique tissue. PGs play important roles in organizing the bone extracellular matrix, taking part in the structuring of the tissue itself as active regulators of collagen fibrillogenesis. PGs also display selective patterns of reactivity with several constituents including cytokines and growth factors, such as transforming growth factor-beta or osteoprotegerin thereby modulating their bio-availability and biological activity in the bone tissue. In this review, the complex PG composition in bone will be addressed together with the specific role played by PGs (or their GAGs chains) in bone biology, as regulatory molecules for bone resorption and their involvement in bone tumor development. These roles have been determined after modulation of PG expression or mutations in their corresponding genes, which revealed specific roles for these compounds in bone pathologies (e.g. perlecan or glypican-3 mutations observed respectively in chondrodysplasia or dysmorphic syndrome). Finally, the potential therapeutic interest of PGs is discussed based on recent data, more particularly on bone tumor-associated osteolysis as these molecules are involved both in bone resorption and tumor development.     

Lost in disruption: Role of proteases in glioma invasion and progression

A characteristic feature of malignant glial tumors (gliomas) is their tendency to diffusely infiltrate the nervous system preventing their complete surgical resection. Proteases play a decisive role in this malignant process, either by degradation of brain extracellular matrix (ECM) components, adhesion molecules, or by regulating the activity of growth and chemotactic factors. Secreted matrix metalloproteinases (MMPs) and ADAMTS proteases (ADAMs with thrombospondin motifs) cleave different ECM components like the proteoglycans (lecticans) aggrecan, versican, neurocan and brevican with selective preferences; they are further regulated by endogenous inhibitors and activating metallo- and serine proteases. Cell surface proteases of the ADAM family (A Disintegrin And Metalloproteinase), but also serine proteases regulate the activity of growth factors and chemokines that act as autocrine / paracrine stimulators within gliomas. Thus, proteases play a decisive role for the spread and growth of gliomas and are prominent targets for their therapy.     

Lost in disruption: Role of proteases in glioma invasion and progression

A characteristic feature of malignant glial tumors (gliomas) is their tendency to diffusely infiltrate the nervous system preventing their complete surgical resection. Proteases play a decisive role in this malignant process, either by degradation of brain extracellular matrix (ECM) components, adhesion molecules, or by regulating the activity of growth and chemotactic factors. Secreted matrix metalloproteinases (MMPs) and ADAMTS proteases (ADAMs with thrombospondin motifs) cleave different ECM components like the proteoglycans (lecticans) aggrecan, versican, neurocan and brevican with selective preferences; they are further regulated by endogenous inhibitors and activating metallo- and serine proteases. Cell surface proteases of the ADAM family (A Disintegrin And Metalloproteinase), but also serine proteases regulate the activity of growth factors and chemokines that act as autocrine / paracrine stimulators within gliomas. Thus, proteases play a decisive role for the spread and growth of gliomas and are prominent targets for their therapy.     

Evidence for the Heparin-Binding Ability of the Ascidian Xlink Domain and Insight into the Evolution of the Xlink Domain in Chordates

The vertebrate Xlink domain is found in two types of genes: lecticans and their associated hyaluronan-and-proteoglycan-binding-link-proteins (HAPLNs), which are components of the extracellular matrix, and those represented by CD44 and stabilins, which are expressed on the surface of lymphocytes. In both types of genes, Xlink functions as a hyaluronan binding domain. We have already reported that protochordate ascidians possess only the latter type of gene. The present analysis of the expression of ascidian Xlink domain genes revealed that these genes function in blood cell migration and apoptosis. While the Xlink domain is found in various metazoans, including ascidians and nematodes, hyaluronan is believed to be specific for vertebrates. In comprehensive genome surveys for hyaluronan synthase (HAS), we found no HAS gene in ascidians. We also established that hyaluronan is absent from the ascidian body biochemically. Therefore, ascidians possess the Xlink domain, but they lack HA. We recovered one ascidian Xlink domain gene that encoded a heparin-binding protein, although it shows no affinity for hyaluronan. Based on these findings, we conclude that in invertebrates, the Xlink domain serves as heparin-binding protein domain and functions in blood cell migration and apoptosis. Its binding affinity for HA might have been acquired in the vertebrate lineage.     

Reduced Expression of the Hyaluronan and Proteoglycan Link Proteins in Malignant Gliomas

Malignant gliomas have a distinctive ability to infiltrate the brain parenchyma and disrupt the neural extracellular matrix that inhibits motility of axons and normal neural cells. Chondroitin sulfate proteoglycans (CSPGs) are among the major inhibitory components in the neural matrix, but surprisingly, some are up-regulated in gliomas and act as pro-invasive signals. In the normal brain, CSPGs are thought to associate with hyaluronic acid and glycoproteins such as the tenascins and link proteins to form the matrix scaffold. Here, we examined for the first time the expression of link proteins in human brain and malignant gliomas. Our results indicate that HAPLN4 and HAPLN2 are the predominant members of this family in the adult human brain but are strongly reduced in the tumor parenchyma. To test if their absence was related to a pro-invasive gain of function of CSPGs, we expressed HAPLN4 in glioma cells in combination with the CSPG brevican. Surprisingly, HAPLN4 increased glioma cell adhesion and migration and even potentiated the motogenic effect of brevican. Further characterization revealed that HAPLN4 expressed in glioma cells was largely soluble and did not reproduce the strong, hyaluronan-independent association of the native protein to brain subcellular membranes. Taken together, our results suggest that the tumor parenchyma is rich in CSPGs that are not associated to HAPLNs and could instead interact with other extracellular matrix proteins produced by glioma cells. This dissociation may contribute to changes in the matrix scaffold caused by invasive glioma cells.The extracellular matrix (ECM)² of the adult central nervous system lacks most fibrous proteins (collagens, fibronectin, and laminins) that are present in the matrices of other tissues and is formed instead by a scaffold of hyaluronic acid (HA) with associated glycoproteins (1). The major family of HA binding matrix glycoproteins in the central nervous system is formed by the chondroitin sulfate proteoglycans of the lectican family (aggrecan, versican, neurocan, and brevican), the last two expressed almost exclusively in neural tissue (2). These proteoglycans bind both to HA and to cell-surface receptors (3), regulating the cross-linking and compressibility of the matrix scaffold and, therefore, modulating many neural processes including cell motility during development, axonal navigation, and the stabilization of synapses (4). The lecticans have been identified as a major class of molecules that restrict cellular and axonal motility in neural tissue and are a major component of the glial scar that forms after neural injury and prevents axonal regeneration (5).A second family of HA-binding proteins expressed in the central nervous system is formed by small glycoproteins known as HA- and proteoglycan-link proteins (HAPLNs) or, simply, “link proteins.” These glycoproteins bind both to HA and to the lecticans, forming ternary complexes (6, 7). The structure of the link proteins is remarkably similar to the N-terminal region of the lecticans, and the highly homologous HA binding domains from HAPLNs and lecticans are indistinctly known as proteoglycan tandem repeats or link-protein modules.In a striking example of molecular evolution, the genes of the four HAPLNs are located adjacent to the genes of the four lecticans, indicating a common molecular origin by gene duplication (8). Two of the link proteins, HAPLN2 and HAPLN4, have only been detected in neural tissue, and their genes are adjacent to the neural-specific proteoglycans, brevican and neurocan, respectively (8). Both HAPLN2 and HAPLN4, also known as brain-specific link protein (Bral-1) and Bral-2, are up-regulated in the adult central nervous system and match the temporal expression profile of brevican, which is the most abundant CSPG in adult neural tissue (9, 10).Current evidence suggests that the HAPLNs may be key components in the organization of the HA-based matrix scaffold. HAPLN1, the best studied member of the family, increases the affinity of the lecticans for HA (11, 12) and stabilizes lectican-HA matrix aggregates (6, 13). Moreover, the increased expression of lecticans and HAPLNs in the adult central nervous system correlates temporally and spatially with changes in ECM solubility and with appearance of ECM aggregates around subsets of neurons, known as “perineuronal nets.” These changes have been associated with restricted cellular motility and decreased synaptic plasticity (14).The role of the lectican CSPGs as inhibitors of motility in the adult central nervous system contrasts starkly with their pro-invasive role in the highly aggressive brain tumors known as malignant gliomas. These are the most common primary tumors of the brain and are characterized by their extensive and diffuse infiltration of the brain parenchyma (15), which makes them impossible to completely remove and facilitates tumor recurrence even after long term therapies. The invasive ability of gliomas is restricted to neural tissue and is not observed in other tumors that metastasize to the brain, suggesting that glioma invasion may be supported in part by unique mechanisms to remodel the neural microenvironment (16).Two lectican CSPGs, versican and the neural-specific CSPG brevican, are highly up-regulated in gliomas compared with normal brain tissue (3). Although these proteoglycans are thought to inhibit the motility of normal glial cells (17, 18), they instead promote glioma cell adhesion and migration. The underlying molecular mechanisms for this unusual effect are poorly understood, although we and others have demonstrated that these lecticans can activate epidermal growth factor receptor signaling in glioma cells, which leads to an increase of cell-surface adhesion molecules (19). Both brevican and versican can also form adhesive complexes with mesenchymal matrix proteins that are present in the glioma ECM but absent from the normal neural ECM (19, 20).Although the role of CSPGs in brain tumors is starting to become better defined, their HAPLN partners have never been analyzed in human brain or in neuropathologies. Therefore, we still have a highly incomplete picture of the molecular changes that occur in the tumor ECM and of how those changes could affect critical aspects of glioma biology such as invasion of the surrounding tissue.We hypothesized that the gain of function of CSPGs in gliomas could be associated with changes in the levels or molecular associations of specific HAPLNs in the ECM of gliomas. Thus, we studied here the expression and biochemical properties of the HAPLN family in human normal brain and glioma tissue. Our results provide the first biochemical characterization of the brain-specific human HAPLN4 and, in addition, show that both neural-specific link proteins HAPLN2 and HAPLN4, which are abundant in adult brain, are virtually absent from the ECM of malignant gliomas.     

Structure and biology of cartilage and bone matrix noncollagenous macromolecules

Over recent years a number of cartilage and bone matrix molecules have been identified and characterized. These include major constituents such as collagens and proteoglycans as well as a number of less-abundant matrix proteins. In several cases these proteins have been characterized by cloning and sequence analysis of the corresponding cDNA. Some properties of the macromolecules have been studied and an understanding of their functions in the structure, assembly, and breakdown of connective tissue matrix is emerging. It appears that some of these molecules have structural roles whereas others participate in the assembly of the tissue. In this paper we attempt to give a current picture of the organization and role of the noncollagenous matrix macromolecules in cartilage and bone.     

Glycans and neural cell interactions

Carbohydrate-carrying molecules in the nervous system have important roles during development, regeneration and synaptic plasticity. Carbohydrates mediate interactions between recognition molecules, thereby contributing to the formation of a complex molecular meshwork at the cell surface and in the extracellular matrix. The tremendous structural diversity of glycan chains allows for immense combinatorial possibilities that might underlie the fine-tuning of cell-cell and cell-matrix interactions.     

The cell surface: the stage for matrix metalloproteinase regulation of migration

Matrix metalloproteinases are important for the turnover of extracellular matrix in tissue. Recent studies have expanded their roles well beyond extracellular matrix degradation - they also cleave many growth factors, cytokines and cell adhesion molecules in the extracellular milieu, modulating their functions irreversibly. In particular, some matrix metalloproteinases that associate with the cell surface have arisen as intriguing regulators of cellular functions, including migration.     

WHERE AM I? HOW A CELL RECOGNIZES ITS POSITIONAL INFORMATION DURING MORPHOGENESIS

Morphogenesis is an old, and one of the latest, fascinating fields in biological science and a huge number of papers on molecular mechanisms underlying it have been published. But most of the works and reviews on these mechanisms pertain to molecules of, as it were, the planning or design of morphogenesis, such as morphogens and homeodomain proteins. In this review, I will describe the function of extracellular matrix (ECM) and other cell adhesion molecules in morphogenesis as that of actual morpho-creating molecules, morphocreators, and discuss their roles as positional information-pertaining molecules.     

Basement membrane proteoglycans: Modulators <Emphasis Type="Italic">Par Excellence</Emphasis> of cancer growth and angiogenesis

Proteoglycans located in basement membranes, the nanostructures underling epithelial and endothelial layers, are unique in several respects. They are usually large, elongated molecules with a collage of domains that share structural and functional homology with numerous extracellular matrix proteins, growth factors and surface receptors. They mainly carry heparan sulfate side chains and these contribute not only to storing and preserving the biological activity of various heparan sulfate-binding cytokines and growth factors, but also in presenting them in a more Ȍactive configurationȍ to their cognate receptors. Abnormal expression or deregulated function of these proteoglycans affect cancer and angiogenesis, and are critical for the evolution of the tumor microenvironment. This review will focus on the functional roles of the major heparan sulfate proteoglycans from basement membrane zones: perlecan, agrin and collagen XVIII, and on their roles in modulating cancer growth and angiogenesis.     

Selective Decline of Synaptic Protein Levels in the Frontal Cortex of Female Mice Deficient in the Extracellular Metalloproteinase ADAMTS1

The chondroitin sulfate-bearing proteoglycans, also known as lecticans, are a major component of the extracellular matrix (ECM) in the central nervous system and regulate neural plasticity. Growing evidence indicates that endogenous, extracellular metalloproteinases that cleave lecticans mediate neural plasticity by altering the structure of ECM aggregates. The bulk of this in vivo data examined the matrix metalloproteinases, but another metalloproteinase family that cleaves lecticans, a disintegrin and metalloproteinase with thrombospondin motifs (ADAMTS), modulates structural plasticity in vitro, although few in vivo studies have tested this concept. Thus, the purpose of this study was to examine the neurological phenotype of a mouse deficient in ADAMTS1. Adamts1 mRNA was absent in the ADAMTS1 null mouse frontal cortex, but there was no change in the abundance or proteolytic processing of the prominent lecticans brevican and versican V2. However, there was a marked increase in the perinatal lectican neurocan in juvenile ADAMTS1 null female frontal cortex. More prominently, there were declines in synaptic protein levels in the ADAMTS1 null female, but not male, frontal cortex beginning at postnatal day 28. These synaptic marker declines did not affect learning or memory in the adult female ADAMTS1 null mice when tested with the radial-arm water maze. These results indicate that in vivo Adamts1 knockout leads to sexual dimorphism in frontal cortex synaptic protein levels. Since changes in lectican abundance and proteolytic processing did not accompany the synaptic protein declines, ADAMTS1 may play a nonproteolytic role in regulating neural plasticity.     

Brain extracellular matrix

The extracellular matrix of the adult brain tissue has a uniquecomposition. The striking feature of this matrix is the prominenceof lecticans, proteoglycans that contain a lectin domain anda hyaluronic acid-binding domain. Hyaluronic acid and tenascinfamily adhesive/anti-adhesive proteins are also abundant. Matrixproteins common in other tissues are nearly absent in adultbrain. The brain extracellular matrix appears to have trophiceffects on neuronal cells and affect neurite outgrowth. Theunique composition of this matrix may be responsible for theresistance of brain tissue toward invasion by tumors of non-neuronalorigin. extracellular matrix lectican versican review     

Functions of heparan sulfate proteoglycans in cell signaling during development

Heparan sulfate proteoglycans (HSPGs) are cell-surface and extracellular matrix macromolecules that are composed of a core protein decorated with covalently linked glycosaminoglycan (GAG) chains. In vitro studies have demonstrated the roles of these molecules in many cellular functions, and recent in vivo studies have begun to clarify their essential functions in development. In particular, HSPGs play crucial roles in regulating key developmental signaling pathways, such as the Wnt, Hedgehog, transforming growth factor-beta, and fibroblast growth factor pathways. This review highlights recent findings regarding the functions of HSPGs in these signaling pathways during development.     

Matrix Proteins in the Outer Shells of Molluscs

The shells of molluscs are composed mainly of calcium carbonate crystals, with small amounts of matrix proteins. For more than 50 years, they have attracted attention for their unique mechanical and biological properties. Only recently, however, have researchers begun to realize that it is the matrix proteins that control the formation of calcium carbonate crystals and play key roles in their extraordinary properties, despite the fact that matrix proteins comprise less than 5% of the shell weight. This article reviews the matrix proteins identified to date from the shells of molluscs, their structural characteristics, and their roles in shell formation. Some suggestions are given for further investigation based on the summary and analysis.     

The role of mucins in host-parasite interactions: Part II - helminth parasites

Some parasites express mucin-like molecules. These have possible roles in attachment and invasion of host cells and in the avoidance of host immune processes. Enzymes of parasite origin might also facilitate infection, either by degrading host mucus barriers or by generating binding sites on host cells. Host mucins have roles in preventing parasite establishment or in parasite expulsion. They, in turn, might be exploited by parasites, either as sources of fuel or binding sites, or as host-finding targets. Here, we describe the biochemical properties of mucins and mucin-like molecules in relation to interactions (established and putative) between helminth parasites and their hosts.     

The extracellular matrix dimension of skeletal muscle development

Cells anchor to substrates by binding to extracellular matrix (ECM). In addition to this anchoring function however, cell–ECM binding is a mechanism for cells to sense their surroundings and to communicate and coordinate behaviour amongst themselves. Several ECM molecules and their receptors play essential roles in muscle development and maintenance. Defects in these proteins are responsible for some of the most severe muscle dystrophies at every stage of life from neonates to adults. However, recent studies have also revealed a role of cell–ECM interactions at much earlier stages of development as skeletal muscle forms. Here we review which ECM molecules are present during the early phases of myogenesis, how myogenic cells interact with the ECM that surrounds them and the potential consequences of those interactions. We conclude that cell–ECM interactions play significant roles during all stages of skeletal muscle development in the embryo and suggest that this “extracellular matrix dimension” should be added to our conceptual network of factors contributing to skeletal myogenesis.     

胶原样分子与肿瘤关系研究进展

细胞外基质不仅维持着体内细胞微环境的稳定,还在细胞的正常生长、增殖以及细胞之间的信号传导中起着重要作用。肿瘤发生时,基质中的分子组分发生了改变,这些改变朝着有利于肿瘤细胞生长侵袭的方向发展。在这个过程中,细胞外基质的主要成分在合成和分解上发生巨大变化,胶原分子便是其中之一,胶原分子作为细胞外基质中的主要成分,对细胞的黏附、运动、迁移等活动起着重要作用。随着研究的深入,发现越来越多的胶原分子参与了肿瘤的发生发展。基质中还存在着一些分子,它们在结构上和胶原蛋白一样含有三螺旋胶原结构域,在肿瘤的发生发展过程中同样发挥着重要作用。本文就包括胶原分子在内的含有胶原结构的分子在肿瘤中的作用做一综述。     

The proteoglycan lectin domain binds sulfated cell surface glycolipids and promotes cell adhesion

The lecticans are a group of chondroitin sulfate proteoglycans characterized by the presence of C-type lectin domains. Despite the suggestion that their lectin domains interact with carbohydrate ligands, the identity of such ligands has not been elucidated. We previously showed that brevican, a nervous system-specific lectican, binds the surface of B28 glial cells (Yamada, H., Fredette, B., Shitara, K., Hagihara, K., Miura, R., Ranscht, B., Stallcup, W. B., and Yamaguchi, Y. (1997) J. Neurosci. 17, 7784-7795). In this paper, we demonstrate that two classes of sulfated glycolipids, sulfatides and HNK-1-reactive sulfoglucuronylglycolipids (SGGLs), act as cell surface receptors for brevican. The lectin domain of brevican binds sulfatides and SGGLs in a calcium-dependent manner as expected of a C-type lectin domain. Intact, full-length brevican also binds both sulfatides and SGGLs. The lectin domain immobilized as a substrate supports adhesion of cells expressing SGGLs or sulfatides, which was inhibited by monoclonal antibodies against these glycolipids or by treatment of the substrate with SGGLs or sulfatides. Our findings demonstrate that the interaction between the lectin domains of lecticans and sulfated glycolipids comprises a novel cell substrate recognition system, and suggest that lecticans in extracellular matrices serve as substrate for adhesion and migration of cells expressing these glycolipids in vivo.