M K Sardana

The venom protein, s-echistatin, originally derived from the saw-scaled viper Echis carinatus, was found to be a potent inhibitor of bone resorption by isolated osteoclasts. This Arg24-Gly25-Asp26-(RGD)-containing protein inhibited the excavation of bone slices by rat osteoclasts (IC50 = 0.1 nM). It also inhibited the release of [3H]proline from labeled bone particles by chicken osteoclasts (IC50 = 100 nM). By comparison, the tetrapeptide Arg-Gly-Asp-Ser (RGDS) inhibited resorption by rat or chicken osteoclasts with an IC50 of 0.1 mM while ala24-echistatin was inactive. Video microscopy showed that rat osteoclast attachment to substrate was more sensitive to s-echistatin than was the attachment of mononuclear cells or chicken osteoclasts. The difference in sensitivity of rat and chicken osteoclasts to s-echistatin may be due to differences between receptors on rat and chicken osteoclasts for s-echistatin. Antibody localization of echistatin on these cells showed much greater echistatin binding to rat osteoclasts than to chicken osteoclasts. Laser scanning confocal microscopy after immunohistochemical staining showed that s-echistatin binds to osteoclasts, that s-echistatin receptors are most abundant at the osteoclast/glass interface, and that s-echistatin colocalizes with vinculin. Confocal interference reflection microscopy of osteoclasts incubated with s-echistatin, demonstrated colocalization of s-echistatin with the outer edges of clusters of grey contacts at the tips of some lamellipodia. Identification of the echistatin receptor as an integrin was confirmed by colocalization of echistatin fluorescence with staining for an alpha-like subunit. Attachment of bone particles labeled with [3H]proline to chicken osteoclasts confirmed that the mechanism of action of echistatin was to inhibit osteoclast binding to bone presumably by disrupting adhesion structures. These data demonstrate that osteoclasts bind to bone via an RGD-sequence as an obligatory step in bone resorption, that this RGD-binding integrin is at adhesion structures, and that it colocalizes with vinculin and has an alpha-like subunit.

Tin(IV)-protoporphyrin (Sn-protoporphyrin) potently inhibits heme degradation to bile pigments in vitro and in vivo, a property that confers upon this synthetic compound the ability to suppress a variety of experimentally induced and naturally occurring forms of jaundice in animals and humans. Utilizing rat liver heme oxygenase purified to homogeneity together with appropriate immunoquantitation techniques, we have demonstrated that Sn-protoporphyrin possesses the additional property of potently inducing the synthesis of heme oxygenase protein in liver cells while, concurrently, completely inhibiting the activity of the newly formed enzyme. Substitution of tin for the central iron atom of heme thus leads to the formation of a synthetic heme analogue that regulates heme oxygenase by a dual mechanism, which involves competitive inhibition of the enzyme for the natural substrate heme and simultaneous enhancement of new enzyme synthesis. Cobaltic(III)-protoporphyrin (Co-protoporphyrin) also inhibits heme oxygenase activity in vitro, but unlike Sn-protoporphyrin it greatly enhances the activity of the enzyme in the whole animal. Co-protoporphyrin also acts as an in vivo inhibitor of heme oxygenase; however, its inducing effect on heme oxygenase synthesis is so pronounced as to prevail in vivo over its inhibitory effect on the enzyme. These studies show that certain synthetic heme analogues possess the ability to simultaneously inhibit as well as induce the enzyme heme oxygenase in liver. The net balance between these two actions, as reflected in the rate of heme oxidation activity in the whole animal, appears to be influenced by the nature of the central metal atom of the synthetic metalloporphyrin.

Antistasin is a 119-amino acid protein isolated from the salivary glands of the Mexican leech Haementeria officinalis. The determination of the primary structure of antistasin revealed that the protein is highly disulfide-bonded with a 2-fold internal homology. Antistasin exhibits a potent anticoagulant activity purportedly due to the selective inhibition of Factor Xa (Tuszinsky, G. P., Gasic, T. B., and Gasic, G. J. (1987) J. Biol. chem. 262, 9718-9723). In the present study a detailed kinetic analysis of the inhibitory interaction between antistasin and Factor Xa was performed. In addition, the specificity of antistasin was examined by testing its ability to inhibit a variety of serine proteinases. Utilizing purified antistasin and a tripetidyl p-nitroanilide substrate, antistasin was shown to act as a reversible inhibitor of Factor Xa which exhibits slow-tight binding kinetics. Antistasin reacts stoichiometrically with Factor Xa with inhibition displaying a mixed, primarily competitive type. The inhibition is partial in the presence of Ca2+ and becomes complete in the absence of Ca2+. The estimated dissociation constant for the enzyme-inhibitor complex is between 0.31 and 0.62 nM. After binding to Factor Xa, antistasin is cleaved at a single site to yield a modified inhibitor. Automated gas-phase sequence analysis of the modified inhibitor indicates the arginine residue at position 34 in antistasin occupies the P1 position of the reactive site. These data indicate that the leech has evolved a highly selective and potent inhibitor of coagulation Factor Xa that shares several mechanistic similarities with other serine proteinase inhibitors.

The protease domain of the hepatitis C virus (HCV) protein NS3 was expressed in Escherichia coli, purified to homogeneity, and shown to be active on peptides derived from the sequence of the NS4A-NS4B junction. Experiments were carried out to optimize protease activity. Buffer requirements included the presence of detergent, glycerol, and dithiothreitol, pH between 7.5 and 8.5, and low ionic strength. C- and N-terminal deletion experiments defined a peptide spanning from the P6 to the P4' residue as a suitable substrate. Cleavage kinetics were subsequently measured by using decamer P6-P4' peptides corresponding to all intermolecular cleavage sites of the HCV polyprotein. The following order of cleavage efficiency, in terms of kcat/Km, was determined: NS5A-NS5B > NS4A-NS4B >> NS4B-NS5A. A 14-mer peptide containing residues 21 to 34 of the protease cofactor NS4A (Pep4A 21-34), when added in stoichiometric amounts, was shown to increase cleavage rates of all peptides, the largest effect (100-fold) being observed on the hydrolysis of the NS4B-NS5A decamer. From the kinetic analysis of cleavage data, we conclude that (i) primary structure is an important determinant of the efficiency with which each site is cleaved during polyprotein processing, (ii) slow cleavage of the NS4B-NS5A site in the absence of NS4A is due to low binding affinity of the enzyme for this site, and (iii) formation of a 1:1 complex between the protease and Pep4A 21-34 is sufficient and required for maximum activation.

Tick anticoagulant peptide (TAP) is a potent, highly selective inhibitor of blood coagulation factor Xa (Waxman, L., Smith, D. E., Arcuri, K. E., and Vlasuk, G. P. (1990) Science, 248, 593-596). Further detailed studies pertaining to the in vitro and in vivo evaluation of TAP require quantities of the inhibitor which cannot be isolated from ticks. To overcome this limitation we describe here the characterization of recombinant TAP (rTAP) secreted by Saccharomyces cerevisiae. Expression of rTAP was obtained using a chimeric gene containing a fusion between sequences encoding the secretory preproleader of the yeast mating pheromone alpha-factor and a synthetic sequence encoding the 60-amino acid inhibitor under the transcriptional control of a galactose-inducible promoter. Recombinant S. cerevisiae were found to secrete biologically active rTAP into the extracellular medium at levels of 0.1-0.15 g/liter. The secreted inhibitor was purified to homogeneity and found to be indistinguishable from the native inhibitor with respect to several criteria, including primary structure, amino acid composition, and electrophoretic mobility. In addition, purified rTAP and native TAP exhibited similar stoichiometric inhibition of factor Xa in vitro. The in vivo efficacy of rTAP was demonstrated using a model of low grade disseminated intravascular coagulation where the purified inhibitor was shown to significantly inhibit thromboplastin-induced fibrinopeptide A generation following an infusion into conscious rhesus monkeys. The availability of rTAP will allow a detailed evaluation of the in vitro and in vivo properties of this highly specific and potent factor Xa inhibitor.