Deane F. Mosher

Thrombospondins Are Astrocyte-Secreted Proteins that Promote CNS Synaptogenesis

The establishment of neural circuitry requires vast numbers of synapses to be generated during a specific window of brain development, but it is not known why the developing mammalian brain has a much greater capacity to generate new synapses than the adult brain. Here we report that immature but not mature astrocytes express thrombospondins (TSPs)-1 and -2 and that these TSPs promote CNS synaptogenesis in vitro and in vivo. TSPs induce ultrastructurally normal synapses that are presynaptically active but postsynaptically silent and work in concert with other, as yet unidentified, astrocyte-derived signals to produce functional synapses. These studies identify TSPs as CNS synaptogenic proteins, provide evidence that astrocytes are important contributors to synaptogenesis within the developing CNS, and suggest that TSP-1 and -2 act as a permissive switch that times CNS synaptogenesis by enabling neuronal molecules to assemble into synapses within a specific window of CNS development.

Gabapentin Receptor α2δ-1 Is a Neuronal Thrombospondin Receptor Responsible for Excitatory CNS Synaptogenesis

Synapses are asymmetric cellular adhesions that are critical for nervous system development and function, but the mechanisms that induce their formation are not well understood. We have previously identified thrombospondin as an astrocyte-secreted protein that promotes central nervous system (CNS) synaptogenesis. Here, we identify the neuronal thrombospondin receptor involved in CNS synapse formation as alpha2delta-1, the receptor for the anti-epileptic and analgesic drug gabapentin. We show that the VWF-A domain of alpha2delta-1 interacts with the epidermal growth factor-like repeats common to all thrombospondins. alpha2delta-1 overexpression increases synaptogenesis in vitro and in vivo and is required postsynaptically for thrombospondin- and astrocyte-induced synapse formation in vitro. Gabapentin antagonizes thrombospondin binding to alpha2delta-1 and powerfully inhibits excitatory synapse formation in vitro and in vivo. These findings identify alpha2delta-1 as a receptor involved in excitatory synapse formation and suggest that gabapentin may function therapeutically by blocking new synapse formation.

High molecular weight, cell surface-associated glycoprotein (fibronectin) lost in maglinant transformation

Abstract Fibronectin is a polymorphic glycoprotein found in blood and tissues of vertebrates and in cultures of adherent vertebrate cells. There are several forms of fibronectin is composed of two high molecular weight subunits held together by forms found in tissues and on and around the surfaces of cultured cells. Soluble fibronectin is composed of two high molecular weight subunits held together by disulfide bonds. Insoluble fibronectin may be covalently cross-linked in larger complexes. Fibronectin has affinities for collagen, fibrin, heparin, and cell surfaces. in culture, fibronectin in growth medium may mediate attachment of cells to substratum, and fibronectin synthesized by cells may mediate adhesion to substratum. The widespread occurrence of fibronectin in basal lamina indicates that many different cell types in vivo abut against a fibronectin-containing matrix. Cultured transformed cells usually lack cell-surface fibronectin, also called large, external transformation-sensitive (LETS) protein. The failure of transformed cells to synthesize or bind fibronectin is paralleled (at least in some systems) by failures to synthesize or bind collagen and proteoglycans. Abnormal synthesis of fibronectin and other matrix components and abnormal interactions with the tissue matrix may account for several phenotypic characteristics of transformed cultutred cells and for some of the malignant behavior of neoplastic cells in vivo.

Polymerization of type I and III collagens is dependent on fibronectin andenhanced by integrins alpha 11beta 1 and alpha 2beta 1.

Polymerization of the ECM proteins fibronectin and laminin has been shown to take place in close vicinity to the cell surface and be facilitated by β1integrins (Lohikangas, L., Gullberg, D., and Johansson, S. (2001) Exp. Cell Res. 265, 135–144 and Wennerberg, K., Lohikangas, L., Gullberg, D., Pfaff, M., Johansson, S., and Fassler, R. (1996) J. Cell Biol. 132, 227–238). We have studied the role of collagen receptors, integrins α11β1 and α2β1, and fibronectin in collagen polymerization using fibronectin-deficient mouse embryonic fibroblast cell lines. In contrast to the earlier belief that collagen polymerization occurs via self-assembly of collagen molecules we show that a preformed fibronectin matrix is essential for collagen network formation and that collagen-binding integrins strongly enhance this process. Thus, collagen deposition is regulated by the cells, both indirectly through integrin α5β1-dependent polymerization of fibronectin and directly through collagen-binding integrins.

Fibronectin Structure, Assembly, and Cardiovascular Implications

In the past 2 decades, it has been appreciated that the functions of the extracellular matrix (ECM) are not entirely structural. ECM components interact with specific adhesion receptors on cell surfaces and regulate various cellular functions, including differentiation, proliferation, migration, and apoptosis. Fibronectin (FN) is a paradigm adhesive protein, nonreactive with adhesion receptors in its soluble state but highly adhesive when insoluble. Polymerization of FN into the ECM must be tightly regulated to ensure that the adhesive information in the ECM is appropriate. FN exists in a soluble protomeric form in micromolar concentration in blood plasma and in an insoluble multimeric form in the ECM.1 2 Unlike fibrillar or basement membrane collagens, laminins, actin, and tubulin, circulating FN does not self-polymerize in physiologically relevant solutions. Furthermore, there is little passive accumulation of FN in preexisting ECM. Rather, assembly of FN takes place at specialized areas on the cell surface.3 FN is especially abundant in the ECM of embryonic and regenerating or injured tissues, although it can be found in most ECMs, including basement membranes. FN interacts with cells through integrins, heterodimeric transmembrane receptors linking the ECM to the intracellular cytoskeleton and signaling pathways. The aim of this review is to describe the mechanisms and consequences of FN deposition and give a brief overview of the significance of FN for selected areas of cardiovascular research. In the first section we describe important features of the FN molecule that account for its multiple functions. Next, we focus on the assembly process, ie, the conversion of soluble FN to its active, adhesive, insoluble form. Finally, we discuss several areas of cardiovascular research in which FN may have an important role, exemplifying how the adhesive information of FN can drive pathophysiological processes. Soluble FN is a dimeric glycoprotein. Each subunit is a …

Promotion of retinal neurite outgrowth by substratum-bound fibronectin☆

Abstract We have examined conditions under which aggregates of embryonic chick neural retina will extend neurities in vitro. Trypsin-dispersed cells from 7-day embryonic chick neural retina were aggregated in rotation culture for 8 hr and maintained in serum-free medium on a variety of standard culture substrate. Aggregates extend few neurites on untreated plastic, glass, or collagen substrata. However, pretreatment of these substrata with human plasma fibronectin enhances their capacity to support retinal neurite outgrowth. Aggregates cultured on fibronectin-treated substrata extend long, radially oriented neurites within 36 hr in vitro. The morphology of these neurites is distinct from that seen when aggregates are cultured on polylysine-treated substrata. In the latter case, neurites are highly branched and grow concentrically around the aggregate perimeter. Addition of fibronectin to polylysine-treated substrata stimulates radial neurite outgrowth. Promotion of neurite outgrowth is dependent on the amount of fibronectin bound to the culture substratum and on the pH at which binding occurs. The requirements for fibronectin-mediated neurite outgrowth are more stringent than those previously reported for fibroblast attachment and spreading.

Roles of integrins and fibronectin in the entry of Streptococcus pyogenes into cells via protein F1

Entry of group A streptococcus (GAS) into cells has been suggested as an important trait in GAS pathogenicity. Protein F1, a fibronectin (Fn) binding protein, mediates GAS adherence to cells and the extracellular matrix, and efficient cell internalization. We demonstrate that the cellular receptors responsible for protein F1‐mediated internalization of GAS are integrins capable of Fn binding. In HeLa cells, bacterial entry is blocked by anti‐β1 integrin monoclonal antibody. In the mouse cell line GD25, a β1 null mutant, the αvβ3 integrin promotes GAS entry. Internalization of these cells by GAS is blocked by a peptide that specifically binds to αvβ3 integrin. In both cell lines, entry of GAS requires the occupancy of protein F1 by Fn. Neither the 29 kDa nor the 70 kDa N‐terminal fragments or the 120 kDa cell‐binding fragment of Fn promote bacterial entry. Fn‐coated beads are taken up efficiently by HeLa cells. Both the entry of GAS via protein F1 and the uptake of Fn‐coated beads are blocked by anti‐β1 antibody but are unaffected by a large excess of soluble Fn. Internalization of HeLa cells by bacteria bearing increasing amounts of prebound Fn to protein F1 reveals a sigmoidal ultrasensitive curve. These suggest that the ability of particles to interact via Fn with multiple integrin sites plays a central role in their ability to enter cells.

Fibronectin fibrillogenesis regulates three-dimensional neovessel formation

During vasculogenesis and angiogenesis, endothelial cell responses to growth factors are modulated by the compositional and mechanical properties of a surrounding three-dimensional (3D) extracellular matrix (ECM) that is dominated by either cross-linked fibrin or type I collagen. While 3D-embedded endothelial cells establish adhesive interactions with surrounding ligands to optimally respond to soluble or matrix-bound agonists, the manner in which a randomly ordered ECM with diverse physico-mechanical properties is remodeled to support blood vessel formation has remained undefined. Herein, we demonstrate that endothelial cells initiate neovascularization by unfolding soluble fibronectin (Fn) and depositing a pericellular network of fibrils that serve to support cytoskeletal organization, actomyosin-dependent tension, and the viscoelastic properties of the embedded cells in a 3D-specific fashion. These results advance a new model wherein Fn polymerization serves as a structural scaffolding that displays adhesive ligands on a mechanically ideal substratum for promoting neovessel development.

ADAMTS1 mediates the release of antiangiogenic polypeptides from TSP1 and 2

Matrix metalloproteases regulate both physiological and pathological events by processing matrix proteins and growth factors. ADAMTS1 in particular is required for normal ovulation and renal function and has been shown to modulate angiogenesis. Here we report that TSP1 and 2 are substrates of ADAMTS1. Using a combination of mass spectrometry and Edman degradation, we mapped the cleavage sites and characterized the biological relevance of these processing events. ADAMTS1 cleavage mediates the release of polypeptides from the trimeric structure of both TSP1 and 2 generating a pool of antiangiogenic fragments from matrix‐bound thrombospondin. Using neo‐epitope antibodies we confirmed that processing occurs during wound healing of wild‐type mice. However, TSP1 proteolysis is decreased or absent in ADAMTS1 null mice; this is associated with delayed wound closure and increased angiogenic response. Finally, TSP1−/− endothelial cells revealed that the antiangiogenic response mediated by ADAMTS1 is greatly dependent on TSP1. These findings have unraveled a mechanistic explanation for the angiostatic functions attributed to ADAMTS1 and demonstrated in vivo processing of TSP1 under situations of tissue repair.

Assembly of extracellular matrix

A great challenge in understanding how different extracellular matrices assemble is to sort through the vast number of possible interactions between and among matrix molecules. The most profound insights are likely to come from patients with defined defects of matrix molecules and the use of transgenic mice or other experimental technologies that mimic the complexity of the human system.