echistatin and eristostatin

There are key differences between the amino acid residues of the RGD loops and the C termini of echistatin, a potent antagonist of alpha(IIb)beta(3), alpha(v)beta(3) and alpha(5)beta(1), and eristostatin, a similar disintegrin selectively inhibiting alpha(IIb)beta(3). In order to identify echistatin motifs required for selective recognition of alpha(v)beta(3) and alpha(5)beta(1) integrins, we expressed recombinant echistatin, eristostatin, and 15 hybrid molecules. We tested them for their ability to inhibit adhesion of different cell lines to fibronectin and von Willebrand factor and to express ligand-induced binding site epitope. The results showed that Asp(27) and Met(28) support recognition of both alpha(v)beta(3) and alpha(5)beta(1). Replacement of Met(28) with Asn completely abolished echistatin's ability to recognize each of the integrins, while replacement of Met(28) with Leu selectively decreased echistatin's ability to recognize alpha(5)beta(1) only. Eristostatin in which C-terminal WNG sequence was substituted with HKGPAT exhibited new activity with alpha(5)beta(1), which was 10-20-fold higher than that of wild type eristostatin. A hypothesis is proposed that the C terminus of echistatin interacts with separate sites on beta(1) and beta(3) integrin molecules.

Topics: Amino Acid Sequence; Animals; CHO Cells; Cricetinae; Intercellular Signaling Peptides and Proteins; Molecular Sequence Data; Mutation; Peptides; Receptors, Fibronectin; Receptors, Vitronectin; Recombinant Proteins; Sequence Homology, Amino Acid; Viper Venoms

Peptides containing the integrin recognition sequence, RGD, can inhibit experimental metastasis of mouse melanoma cells, but the integrin(s) affected in these experiments is unknown. Besides "classical" RGD-binding integrins such as alpha 5 beta 1 and alpha v beta 3, RGD has been reported to bind alpha 4 beta 1, and mAbs to alpha 4 beta 1 can inhibit melanoma metastasis. We investigated the mode of action of the disintegrin eristostatin, an RGD-containing peptide isolated from snake venom, in a human melanoma experimental metastasis model. Lung colonization following i.v. injection of MV3 cells in nude mice was strongly inhibited by eristostatin. MV3 cells bound FITC-eristostatin and adhered to eristostatin-coated wells. This adhesion was partially inhibited by a GRGDSP peptide and by alpha 4 mAb. Binding of FITC-eristostatin to Jurkat cells and adhesion of Jurkat (but not K562) cells to eristostatin-coated wells further suggested that eristostatin binds alpha 4 beta 1, even though, again, alpha 4 mAb only partially inhibited adhesion. Expression of alpha 4 beta 1 was enhanced in metastatic melanoma cells compared to normal melanocytes and nonmetastatic melanoma cells. Finally, eristostatin inhibited adhesion of both MV3 and CHO alpha 4 cells to the alpha 4 beta 1-ligand VCAM-1, while adhesion to other ligands via other integrins was not affected. These findings demonstrate that inhibition of melanoma cell metastasis by RGD-containing peptides such as eristostatin, may be due to interference with alpha 4 beta 1-VCAM binding, in addition to inhibition of the classical RGD-binding integrins.

Topics: Animals; Binding Sites; Humans; Infant, Newborn; Integrin alpha4beta1; Integrins; Intercellular Signaling Peptides and Proteins; Male; Melanocytes; Melanoma; Mice; Mice, Nude; Neoplasm Metastasis; Oligopeptides; Peptides; Platelet Aggregation Inhibitors; Receptors, Lymphocyte Homing; Skin; Skin Neoplasms; Snake Venoms; Viper Venoms

Echistatin and eristostatin are structurally homologous distintegrins which exhibit significant functional differences in interaction with various integrins. We hypothesized that this may reflect differences in the sequences of their RGD loops: 20CKRARGDDMDDYC32 AND 23CRVARGDWNDDYC35, respectively. Mapping of eristostatin peptides obtained by proteolytic digestion suggested that it has the same alignment of S-S bridges as echistatin. Synthetic echistatin D27W resembled eristostatin since it had increased platelet aggregation inhibitory activity, increased potency to block fibrinogen binding to alpha IIb beta 3, and decreased potency to block vitronectin binding to alpha v beta 3 as compared to wild-type echistatin. Since eristostatin and echistatin have a similar pattern of disulfide bridges, we constructed molecular models of eristostatin based on echistatin NMR coordinates. The RGD loops of eristostatin and echistatin D27W were wider than echistatin's due to the placement of tryptophan (rather than aspartic acid) immediately after the RGD sequence. We propose a hypothesis that the width and shape of the RGD loop are important ligand structural features that affect fitting of ligand to the binding pocket of alpha IIb beta 3 and alpha v beta 3.

Topics: Amino Acid Sequence; Animals; CHO Cells; Computer Simulation; Cricetinae; Disulfides; Humans; Intercellular Signaling Peptides and Proteins; Molecular Sequence Data; Mutagenesis, Site-Directed; Oligopeptides; Oxalates; Oxalic Acid; Peptide Fragments; Peptides; Platelet Aggregation Inhibitors; Platelet Glycoprotein GPIIb-IIIa Complex; Point Mutation; Protein Structure, Secondary; Receptors, Vitronectin; Recombinant Proteins; Thermodynamics; Transfection; Trypsin; Viper Venoms; Viperidae

Two disintegrins with a high degree of amino acid sequence similarity, echistatin and eristostatin, showed a low level of interaction with Chinese hamster ovary (CHO) cells, but they bound to CHO cells transfected with alpha IIb beta 3 genes (A5 cells) and to CHO cells transfected with alpha v beta 3 genes (VNRC3 cells) in a reversible and saturable manner. Scatchard analysis revealed that eristostatin bound to 816000 sites per A5 cell (Kd 28 nM) and to 200000 sites (Kd 14 nM) per VNRC3 cell respectively. However, VNRC3 cells did not bind to immobilized eristostatin. Echistatin bound to 495000 sites (Kd 53 nM) per A5 cell and to 443000 sites (Kd 20 nM) per VNRC3 cell. As determined by flow cytometry, radiobinding assay and adhesion studies, binding of both disintegrins to A5 cells and resting platelets and binding of echistatin to VNRC3 cells resulted in the expression of ligand-induced binding sites (LIBS) on the beta 3 subunit. Eristostatin inhibited, more strongly than echistatin, the binding of three monoclonal antibodies: OPG2 (RGD motif dependent), A2A9 (alpha IIb beta 3 complex dependent) and 7E3 (alpha IIb beta 3 and alpha v beta 3 complex dependent) to A5 cells, to resting and to activated platelets and to purified alpha IIb beta 3. Experiments in which echistatin and eristostatin were used alone or in combination to inhibit the binding of 7E3 and OPG2 antibodies to resting platelets suggested that these two disintegrins bind to different but overlapping sites on alpha IIb beta 3 integrin. Monoclonal antibody LM 609 and echistatin seemed to bind to different sites on alpha v beta 3 integrin. However, echistatin inhibited binding of 7E3 antibody to VNRC3 cells and to purified alpha v beta 3 suggesting that alpha v beta 3 and alpha IIb beta 3 might share the same epitope to which both echistatin and 7E3 bind. Eristostatin had no effect in these systems, providing further evidence that it binds to a different epitope on alpha v beta 3.

Topics: Animals; Binding Sites; CHO Cells; Cricetinae; Epitopes; Humans; Intercellular Signaling Peptides and Proteins; Peptides; Platelet Aggregation Inhibitors; Platelet Glycoprotein GPIIb-IIIa Complex; Receptors, Vitronectin; Viper Venoms

Disintegrins, a family of low molecular weight, RGD-containing peptides found in snake venoms prevent the binding of adhesive ligands to a number of integrin receptors. Albolabrin, bitistatin, echistatin, and eristostatin bind to the platelet fibrinogen receptor (GPIIb/IIIa) acting thus as potent inhibitors of platelet aggregation. Here, we have determined the cross-linking of these disintegrins on isolated GPIIb/IIIa. The cross-linking site of all of them was within GPIIIa 217-302, a domain that has been implicated in a number of receptor functions including heterodimer association, activation-dependent conformational changes, and fibrinogen binding.

Topics: Amino Acid Sequence; Binding Sites; Cross-Linking Reagents; Crotalid Venoms; Humans; Intercellular Signaling Peptides and Proteins; Oligopeptides; Peptides; Platelet Aggregation Inhibitors; Platelet Membrane Glycoproteins; Snake Venoms; Viper Venoms

Viper venom disintegrins contain the RGD/KGD motif. They inhibit platelet aggregation and cell adhesion, but show structural and functional heterogeneity. We investigated the interaction of four prototypic disintegrins with alpha IIb beta 3 expressed on the surface of resting and activated platelets. The binding affinity (Kd) of 125I-albolabrin, 125I-echistatin, 125I-bitistatin and 125I-eristostatin toward resting platelets was 294, 153, 48 and 18 nM respectively. The Kd value for albolabrin decreased 3-fold and 6-fold after ADP- or thrombin-induced activation. The Kd values for bitistatin and echistatin also decreased with ADP, but there was no further decrease with thrombin. In contrast, eristostatin bound with the same high affinity to resting and activated platelets. The pattern of fluorescein isothiocyanate (FITC)-eristostatin and FITC-albolabrin binding to resting and activated platelets was consistent with observations using radiolabelled material. Eristostatin showed faster and more irreversible binding to platelets, and greater potency compared with albolabrin in inducing conformational neo-epitopes in beta 3. The anti-alpha IIb beta 3 monoclonal antibody OP-G2 that is RGD-dependent inhibited disintegrin binding to activated platelets more strongly than binding to resting platelets and it inhibited the binding to platelets of albolabrin more strongly than eristostatin. The specificity of disintegrin interaction with alpha IIb beta 3 was confirmed by demonstrating cross-linking of these peptides to alpha IIb beta 3 on normal platelets, but not to thrombasthenic platelets deficient in alpha IIb beta 3.

Topics: Adenosine Diphosphate; Blood Platelets; Cross-Linking Reagents; Crotalid Venoms; Disintegrins; Fluorescein-5-isothiocyanate; Fluorescent Dyes; Humans; Intercellular Signaling Peptides and Proteins; Iodine Radioisotopes; Peptides; Platelet Activation; Platelet Aggregation Inhibitors; Platelet Membrane Glycoproteins; Snake Venoms; Viper Venoms