Stephan Niland

Decorin Regulates Endothelial Cell Motility on Collagen I through Activation of Insulin-like Growth Factor I Receptor and Modulation of α2β1 Integrin Activity

The proteoglycan decorin is expressed by sprouting but not quiescent endothelial cells, and angiogenesis is dysregulated in its absence. Previously, we have shown that decorin core protein can bind to and activate insulin-like growth factor-I receptor (IGF-IR) in endothelial cells. In this study, we show that decorin promotes α2β1 integrin-dependent endothelial cell adhesion and migration on fibrillar collagen type I. We provide evidence that decorin modulates cell-matrix interaction in this context by stimulating cytoskeletal and focal adhesion reorganization through activation of the IGF-IR and the small GTPase Rac. Further, the glycosaminoglycan moiety of decorin interacts with α2β1, but not α1β1 integrin, at a site distinct from the collagen I-binding A-domain, to allosterically modulate collagen I-binding activity of the integrin. We propose that induction of decorin expression in angiogenic, as opposed to quiescent, endothelial cells promotes a motile phenotype in an interstitial collagen I-rich environment by both signaling through IGF-IR and influencing α2β1 integrin activity.

Integrin α2β1 is the required receptor for endorepellin angiostatic activity

Endorepellin, the C-terminal module of perlecan, has angiostatic activity. Here we provide definitive genetic and biochemical evidence that the functional endorepellin receptor is the α2β1 integrin. Notably, the specific endorepellin binding to the receptor was cation-independent and was mediated by the α2I domain. We show that the anti-angiogenic effects of endorepellin cannot occur in the absence of α2β1. Microvascular endothelial cells from α2β1-/- mice, but not those isolated from either wild-type or α1β1-/- mice, did not respond to endorepellin. Moreover, syngeneic Lewis lung carcinoma xenografts in α2β1-/- mice failed to respond to systemic delivery of endorepellin. In contrast, endorepellin inhibited tumor growth and angiogenesis in the wild-type mice expressing integrin α2β1. We conclude that the angiostatic effects of endorepellin in vivo are mediated by a specific interaction of endorepellin with the α2β1 integrin receptor.

Collagen XVI harbors an integrin alpha 1 beta 1 recognition site in its C-terminal domains

Collagen XVI is integrated tissue-dependently into distinct fibrillar aggregates, such as D-banded cartilage fibrils and fibrillin-1-containing microfibrils. In skin, the distribution of collagen XVI overlaps that of the collagen-binding integrins α1β1 and α2β1. Basal layer keratinocytes express integrin α2β1, whereas integrin α1β1 occurs in smooth muscle cells surrounding blood vessels, in hair follicles, and on adipocytes. Cells bearing the integrins α1β1 and α2β1 attach and spread on recombinant collagen XVI. Furthermore, collagen XVI induces the recruitment of these integrins into focal adhesion plaques, a principal step in integrin signaling. Of potential physiological relevance, these integrin-collagen XVI interactions may connect cells with specialized fibrils, thus contributing to the organization of fibrillar and cellular components within connective tissues. In cell-free binding assays, collagen XVI is more avidly bound by α1β1 integrin than by α2β1 integrin. Both integrins interact with collagen XVI via the A domain of their α subunits. A tryptic collagen XVI fragment comprising the collagenous domains 1-3 is recognized by α1β1 integrin. Electron microscopy of complexes of α1β1 integrin with this tryptic collagen XVI fragment or with full-length collagen XVI revealed a unique α1β1 integrin-binding site within collagen XVI located close to its C-terminal end.

Rhodocetin antagonizes stromal tumor invasion in vitro and other α2β1 integrin-mediated cell functions

The pleiotropic effects of Calloselasma rhodostoma venom is caused by various toxins, among them kistrin and ancrod, which block platelet activation triggered by RGD-dependent integrins and the blood clotting cascade, respectively. Here, we demonstrate that rhodocetin, another component of this venom, acts as α2β1 integrin inhibiting disintegrin and antagonizes important cellular responses to type I collagen. Cell adhesion, migration, and collagen lattice contraction in vitro were specifically inhibited by rhodocetin, whereas expression of collagen-degrading matrix metalloproteases was differently modulated. Moreover, cell invasion of HT1080 fibrosarcoma cells into a type I collagen matrix, but not into a fibrin gel or a basement membrane-extracted matrigel was efficiently blocked by rhodocetin. Unlike its natural ligand collagen, rhodocetin failed to cluster α2β1 integrin, despite similar binding affinities. Hence, in the absence of focal adhesions cells do not attach firmly to rhodocetin and do not respond with any of α2β1-triggered cell reactions, except for MMP-1 production. Therefore, this disintegrin may be a valuable tool to specifically target stromal tumor invasion and to manipulate other α2β1 integrin-mediated functions, such as excessive scar contraction and fibrosis. Rhodocetin might be therapeutically useful because of its lack of interference with RGD-dependent integrins, low molecular mass, high solubility, and biochemical stability.

Plumieribetin, a Fish Lectin Homologous to Mannose-binding B-type Lectins, Inhibits the Collagen-binding α1β1 Integrin

Recently, a few fish proteins have been described with a high homology to B-type lectins of monocotyledonous plants. Because of their mannose binding activity, they have been ascribed a role in innate immunity. By screening various fish venoms for their integrin inhibitory activity, we isolated a homologous protein from the fin stings and skin mucus of the scorpionfish (Scorpaena plumieri). This protein inhibits α1β1 integrin binding to basement membrane collagen IV. By protein chemical and spectroscopic means, we demonstrated that this fish protein, called plumieribetin, is a homotetramer and contains a high content of anti-parallel β strands, similar to the mannose-binding monocot B-lectins. It lacks both N-linked glycoconjugates and common O-glycan motifs. Despite its B-lectin-like structure, plumieribetin binds to α1β1 integrin irrespective of N-glycosylation, suggesting a direct protein-protein interaction. This interaction is independent of divalent cations. On the cellular level, plumieribetin failed to completely detach hepatocarcinoma HepG2 cells and primary arterial smooth muscle cells from the collagen IV fragment CB3. However, plumieribetin weakened the cell-collagen contacts, reduced cell spreading, and altered the actin cytoskeleton, after the compensating α2β1 integrin was blocked. The integrin inhibiting effect of plumieribetin adds a new function to the B-lectin family, which is known for pathogen defense.

The α2β1 integrin-specific antagonist rhodocetin is a cruciform, heterotetrameric molecule

The integrin α2β1 plays an important role in various pathophysiological processes, such as thrombosis, wound healing, inflammation, and metastasis. Rhodocetin, a constituent of the venom of the hemorrhagic Malayan pit viper (Calloselasma rhodostoma), is a specific α2β1 integrin antagonist. To understand its molecular mode of action, its structure was studied by crystallography. Its quaternary structure in solution was also analyzed biochemically. Two novel subunits of rhodocetin were sequenced by mass spectrometry. Their integrin binding was measured by protein interaction ELISAs. Rhodocetin is a C‐type lectinlike protein (CLP) consisting of four homologous, yet distinct, subunits, α, β, γ, and δ, the latter two of which have been unknown to date. With their CLP folds and loop‐swapping motifs, the subunits α, β and γ, δ form two heterodimeric pairs. Uniquely, they arrange orthogonally and shape a cruciform molecule. Bearing a single unpaired cysteine residue, rhodocetin can only form covalent supramolecular complexes with a maximum aggregation number of 2, unlike many heterodimeric CLPs. Being the first heterotetrameric CLP to be crystallized, rhodocetin provides not only the prototypic molecular structure for heterotetrameric CLPs, but also a lead structure for pharmaceutical α2β1 integrin antagonists.—Eble, J. A., Niland, S., Bracht, T., Mormann, M., Peter‐Katalinic, J., Pohlentz, G., Stetefeld, J. The α2β1 integrin‐specific antagonist rhodocetin is a cruciform, heterotetrameric molecule. FASEB J. 23, 2917–2927 (2009). www.fasebj.org

Collagen XXIII, Novel Ligand for Integrin α2β1 in the Epidermis

Cellular receptors for collagens belong to the family of β1 integrins. In the epidermis, integrin α2β1 is the only collagen-binding integrin present. Its expression is restricted to basal keratinocytes with uniform distribution on the cell surface of those cells. Although α2β1 receptors localized at the basal surface interact with basement membrane proteins collagen IV and laminin 111 and 332, no interaction partners have been reported for these integrin molecules at the lateral and apical membranes of basal keratinocytes. Solid phase binding and surface plasmon resonance spectroscopy demonstrate that collagen XXIII, a member of the transmembrane collagens, directly interacts with integrin α2β1 in an ion- and conformation-dependent manner. The two proteins co-localize on the surface of basal keratinocytes. Furthermore, collagen XXIII is sufficient to induce adhesion and spreading of keratinocytes, a process that is significantly reduced in the absence of functional integrin α2β1.

Integrin α7β1 is a redox-regulated target of hydrogen peroxide in vascular smooth muscle cell adhesion

Upon adhesion to laminin-111, aortic smooth muscle cells initially form membrane protrusions with an average diameter of 2.9μm. We identified these protrusions also as subcellular areas of increased redox potential and protein oxidation by detecting cysteine sulfenic acid groups with dimedone. Hence, we termed these areas oxidative hot spots. They are spatially and temporally transient during an early stage of adhesion and depend on the activity of the H(2)O(2)-generating NADPH oxidase 4. Presumably located on cellular protrusions, integrin α7β1 mediates adhesion and migration of vascular smooth muscle cells to laminins of their surrounding basement membrane. Using protein chemistry and mass spectrometry, two specific oxidation sites within the integrin α7 subunit were identified: one located in its genu region and another within its calf 2 domain. Upon H(2)O(2) treatment, two cysteine residues are oxidized thereby unlocking a disulfide bridge. The genu region is a hinge, around which the integrin domains pivot between a bent/inactive and an upright/active conformation. Also, cysteine oxidation within the calf 2 domain permits conformational changes related to integrin activation. H(2)O(2) treatment of α7β1 integrin in concentrations of up to 100μM increases integrin binding activity to laminin-111, suggesting a physiological redox regulation of α7β1 integrin.

A novel fibrinolytic metalloproteinase, barnettlysin-I from Bothrops barnetti (Barnett´s pitviper) snake venom with anti-platelet properties.

BACKGROUND Viperid snake venoms contain active components that interfere with hemostasis. We report a new P-I class snake venom metalloproteinase (SVMP), barnettlysin-I (Bar-I), isolated from the venom of Bothrops barnetti and evaluated its fibrinolytic and antithrombotic potential. METHODS Bar-I was purified using a combination of molecular exclusion and cation-exchange chromatographies. We describe some biochemical features of Bar-I associated with its effects on hemostasis and platelet function. RESULTS Bar-I is a 23.386 kDa single-chain polypeptide with pI of 6.7. Its sequence (202 residues) shows high homology to other members of the SVMPs. The enzymatic activity on dimethylcasein (DMC) is inhibited by metalloproteinase inhibitors e.g. EDTA, and by α2-macroglobulin. Bar-I degrades fibrin and fibrinogen dose- and time-dependently by cleaving their α-chains. Furthermore, it hydrolyses plasma fibronectin but not laminin nor collagen type I. In vitro Bar-I dissolves fibrin clots made either from purified fibrinogen or from whole blood. In contrast to many other P-I SVMPs, Bar-I is devoid of hemorrhagic activity. Also, Bar-I dose- and time-dependently inhibits aggregation of washed human platelets induced by vWF plus ristocetin and collagen (IC50=1.3 and 3.2 μM, respectively), presumably Bar-I cleaves both vWF and GPIb. Thus, it effectively inhibits vWF-induced platelet aggregation. Moreover, this proteinase cleaves the collagen-binding α2-A domain (160 kDa) of α2β1-integrin. This explains why it additionally inhibits collagen-induced platelet activation. CONCLUSION A non-hemorrhagic but fibrinolytic metalloproteinase dissolves fibrin clots in vitro and impairs platelet function. GENERAL SIGNIFICANCE This study provides new opportunities for drug development of a fibrinolytic agent with antithrombotic effect.

The binding capacity of α1β1-, α2β1- and α10β1-integrins depends on non-collagenous surface macromolecules rather than the collagens in cartilage fibrils

Interactions of cells with supramolecular aggregates of the extracellular matrix (ECM) are mediated, in part, by cell surface receptors of the integrin family. These are important molecular components of cell surface-suprastructures regulating cellular activities in general. A subfamily of β1-integrins with von Willebrand-factor A-like domains (I-domains) in their α-chains can bind to collagen molecules and, therefore, are considered as important cellular mechano-receptors. Here we show that chondrocytes strongly bind to cartilage collagens in the form of individual triple helical molecules but very weakly to fibrils formed by the same molecules. We also find that chondrocyte integrins α1β1-, α2β1- and α10β1-integrins and their I-domains have the same characteristics. Nevertheless we find integrin binding to mechanically generated cartilage fibril fragments, which also comprise peripheral non-collagenous material. We conclude that cell adhesion results from binding of integrin-containing adhesion suprastructures to the non-collagenous fibril periphery but not to the collagenous fibril cores. The biological importance of the well-investigated recognition of collagen molecules by integrins is unknown. Possible scenarios may include fibrillogenesis, fibril degradation and/or phagocytosis, recruitment of cells to remodeling sites, or molecular signaling across cytoplasmic membranes. In these circumstances, collagen molecules may lack a fibrillar organization. However, other processes requiring robust biomechanical functions, such as fibril organization in tissues, cell division, adhesion, or migration, do not involve direct integrin-collagen interactions.