The basic phospholipase A2 from Naja nigricollis venom inhibits the prothrombinase complex by a novel nonenzymatic mechanism

The three phospholipase A2 isoenzymes from Naja nigricollis venom inhibit blood coagulation with different potencies. The strongly anticoagulant basic isoenzyme CM-IV inhibits the prothrombinase complex, whereas the weakly anticoagulant isoenzymes CM-I and CM-II do not. To determine the role of enzymatic activity of the phospholipases in the inhibition of prothrombinase, we varied the time of incubation of each of these isoenzymes with the prothrombinase complex. The inhibition by CM-IV did not increase with time of incubation. CM-I and CM-II failed to inhibit the complex, even with complete hydrolysis of phospholipids in the assay mixture. After alkylation of its active-site histidine, CM-IV lost 97% of its enzymatic activity but retained 60% of its inhibitory potency on prothrombinase. CM-IV also inhibited prothrombinase activity in the absence of phospholipids, whereas CM-I and CM-II did not. The inhibition of the prothrombinase complex by CM-IV is thus not due to its binding to or hydrolysis of phospholipids. The kinetics of CM-IV inhibition of the prothrombinase complex in both the presence and absence of phospholipids was noncompetitive. This inhibition can be explained by binding of CM-IV to either factor Va or Xa, or both, to inhibit the complex. CM-IV differs from previously described nonenzymatic anticoagulants that are proteinase inhibitors or that inhibit the coagulation complexes by interfering with the binding of clotting factors to phospholipids. We conclude that the basic enzyme, CM-IV, inhibits the prothrombinase complex by a novel mechanism independent of enzymatic activity.     

Inhibition of platelet aggregation by a fibrinogenase from Naja nigricollis venom is independent of fibrinogen degradation

Fibrinogenases, proteinases which release peptides from the carboxy-terminal end of fibrinogen, are classified as alpha-fibrinogenases or beta-fibrinogenases, based on their ability to preferentially attack the A alpha or B beta chain, respectively, of fibrinogen. alpha-Fibrinogenases have been shown to inhibit platelet aggregation whereas beta-fibrinogenases do not. We have studied the inhibition of platelet aggregation by proteinase F1, an alpha-fibrinogenase from Naja nigricollis venom. This proteinase inhibits whole blood aggregation in a dose-dependent manner, with an IC50 value of 145 micrograms. However, the proteinase fails to inhibit aggregation in washed platelet suspensions. Thus, proteinase F1 appears to require a plasma factor to cause inhibition. Since fibrinogen acts as an adhesive protein which links platelets during aggregation, and since proteinase F1 cleaves fibrinogen, we investigated the role of fibrinogen in the inhibition of platelet aggregation by proteinase F1. The degradation products of fibrinogen formed by the proteinase did not cause significant inhibition. Thus, the inhibition of platelet aggregation appears to be independent of the formation of fibrinogen degradation products. We also studied the effect of proteinase F1 on aggregation of platelets that were reconstituted with defibrinogenated plasma. The proteinase inhibited aggregation of platelets even in the absence of plasma fibrinogen. Proteinase F1 was about 4-fold more potent in inhibiting platelet aggregation in defibrinogenated blood. From these results, we conclude that the inhibition of platelet aggregation by proteinase F1 from N. nigricollis venom is independent of its action on fibrinogen.     

Cardiotoxic effects of Naja nigricollis venom phospholipase A2 are not due to phospholipid hydrolytic products

N. nigricollis phospholipase A2 (200 micrograms) has marked cardiotoxic actions on the perfused rat heart including the induction of arrhythmias, increases in ventricular thresholds, conduction and resting tension, and decreases in contractile tension. In contrast, perfusion with lysophosphatidyl choline and oleic acid, in concentrations comparable to those estimated to be formed during N. nigricollis treatment, has little effect on cardiac function. The less toxic N. n. atra phospholipase A2 also has little effect on cardiac function even though it causes approximately the same low percentage of phospholipid hydrolysis as produced by N. nigricollis phospholipase A2. Perfusion with albumin did not alter the phospholipase A2 induced changes in cardiac function. Lysophosphatidyl choline in concentrations higher than expected to be formed during N. nigricollis phospholipase A2 treatment, increased conduction time to a greater extent than ventricular threshold whereas the reverse was true for phospholipase A2. We conclude that the cardiotoxic effects of N. nigricollis phospholipase A2 are not due to the accumulation of phospholipid hydrolytic products, and on the basis of prior studies with chemically modified phospholipase A2 enzymes we suggest that N. nigricollis phospholipase A2 has a direct, non-enzymatic, cardiotoxic action.     

Non-enzymatic inhibitors of coagulation and platelet aggregation from Naja nigricollis venom are cardiotoxins

Four non-enzymatic polypeptides from Naja nigricollis crawshawii venom were recently isolated and shown to inhibit plasma coagulation and platelet aggregation. We have now determined the amino acid compositions, amino terminal sequences and direct lytic activity of these anticoagulants. The results of these studies allow us to identify the anticoagulants as cardiotoxins. The anticoagulant activity of these cardiotoxins is far more potent than that of other cardiotoxins previously reported to have anticoagulant activity.     

Isolation and characterization of a cytotoxin P4 from the venom of Naja nigricollis nigricollis preferentially active on tumor cells.

Cytotoxin P4 was isolated from the venom of Naja nigricollis nigricollis in three steps and contained 55% of the crude cytotoxic activity. It had a molecular weight of 8 KD, was stable over a pH range of 1-11 and in boiling water for at least 15 min. It had no measurable enzymatic activities, but was destroyed by proteases. Concentrations of 0.8, 1, 1.2, 25. 20 and 45 ug/ml, were needed to destroy murine melanoma B16 and WEHI 3B leukemia, rat chondrosarcoma, mouse erythrocytes and spleen cells, and human erythrocytes, respectively, thereby showing preferential cytotoxicity to the examined tumor cells. It also prevented the development of the melanoma, leukemia and chondrosarcoma tumors in vivo when mixed with the cells prior to the injection into the animal.     

Targeting of venom phospholipases: the strongly anticoagulant phospholipase A(2) from Naja nigricollis venom binds to coagulation factor Xa to inhibit the prothrombinase complex.

The strongly anticoagulant basic phospholipase A(2) (CM-IV) from Naja nigricollis venom has previously been shown to inhibit the prothrombinase complex of the coagulation cascade by a novel nonenzymatic mechanism (S. Stefansson, R. M. Kini, and H. J. Evans Biochemistry 29, 7742-7746, 1990). That work indicated that CM-IV is a noncompetitive inhibitor and thus it interacts with either factor Va or factor Xa, or both. We further examined the interaction of CM-IV and the protein components of the prothrombinase complex. Isothermal calorimetry studies indicate that CM-IV does not bind to prothrombin or factor Va, but only to factor Xa. CM-IV has no effect on the cleavage of prothrombin by factor Xa in the absence of factor Va. However, in the presence of factor Va, CM-IV inhibits thrombin formation by factor Xa. With a constant amount of CM-IV, raising the concentration of factor Va relieved the inhibition. The phospholipase A(2) enzyme inhibits by competing with factor Va for binding to factor Xa and thus prevents formation of the normal Xa-Va complex or replaces bound factor Va from the complex. Thus factor Xa is the target protein of this anticoagulant phospholipase A(2), which exerts its anticoagulant effect by protein-protein rather than protein-phospholipid interactions.     

Role of tyrosine and tryptophan residues in the structure-activity relationships of a cardiotoxin from Naja nigricollis venom

This paper is an attempt to localize the critical area determining toxicity in a snake cardiotoxin. Toxin gamma is a single-chain polypeptide of 60 amino acids, which has been isolated from the venom of the African spitting cobra, Naja nigricollis. Three aromatic residues, namely, Trp-11, Tyr-22, and Tyr-51, have been individually modified by chemical means. The structure of the native toxin and of each derivative has been carefully investigated by circular dichroism, fluorescence, proton magnetic resonance spectroscopy, and two specific monoclonal antibodies. None of the chemical modifications alters the overall structure of the toxin, which in all cases remains folded into three adjacent loops (I, II, and III) rich in beta-pleated sheet emerging from a small globular region containing four disulfide bridges. A number of subtle changes, however, have been detected in the structure of each derivative compared with that of the native toxin. In particular, nitration of Tyr-51 provoked a structural perturbation in the globular region. Nitration of Tyr-22 induces a more substantial change in the beta-sheet area of the molecule. Thus, the strong inter-ring NOE that is observed in the native toxin between Tyr-22 and Tyr-51 vanishes in the Tyr-22 derivative, and significant changes are observed in the globular region. In contrast, no alteration of the beta-sheet structure of loops II and III has been detected after modification of Trp-11. All changes observed for this derivative remain located in the vicinity of the indole side chain of Trp-11 in loop I. The biological consequences of the modifications were measured: the lethal potency in vivo in mice and the cytotoxic activities in vitro on FL-cells. Lethal activities correlate with cytotoxicity: Tyr-51 modified toxin is equally potent as native toxin, whereas Tyr-22 and Trp-11 derivatized toxins are characterized by substantially lesser activities, the Trp-11 derivatized toxin being the least potent. We conclude that (1) Tyr-51 is not involved in the functional site of the toxin, although it is in interaction with the core of the molecule, (2) Tyr-22 may play a dual structural and functional role, and (3) Trp-11 is in, or in close proximity to, the functional site of the toxin. These data indicate the importance of loop I in determining toxicity of the cardiotoxin.     

Purification of a Class B1 platelet aggregation inhibitor phospholipase A2 from Indian cobra (Naja Naja) venom

A platelet aggregation inhibitor phospholipase A(2) (NND-IV-PLA(2)) was isolated from Naja naja (Eastern India) venom by a combination of cation and anion exchange chromatography. NND-IV-PLA(2) is the most catalytically active enzyme isolated from the Indian cobra venom. The acidic PLA(2) profile of Eastern regional Indian cobra venom is distinctly different from that of the western regional venom. However the acidic PLA(2)s from both the regions follow the pattern of increasing catalytic activity with increase in acidic nature of the PLA(2) isoform. NND-IV-PLA(2) is a Class B1 platelet aggregation inhibitor and inhibits platelet aggregation induced by ADP, collagen and epinephrine. Modification of active site histidine abolishes both catalytic activity and platelet aggregation inhibition activities while aristolochic acid, a phospholipase A(2) inhibitor has only partial effect on the two activities.     

Effect of iodination on the activity of cytotoxin P4 of Naja nigricollis nigricollis.

Iodination of cytotoxin P4, isolated from the venom of Naja nigricollis nigricollis, develops gradually and depends on the molar ratio between the free iodine and the cytotoxin reaching a maximum of two equivalents at a molar ratio of 250 or higher. The cytotoxic activity was also gradually decreased and was totally abolished when one equivalent of iodination was achieved. However, antigenic properties of the cytotoxin were preserved in the iodinated form. When the iodination of the cytotoxin was carried out with a carrier free radiolabeled iodide, the molar ratio was 0.05 resulting in labelling of only 2% of the cytotoxin molecules, which explains the cytotoxicity of the radiolabeled mixture.     

Estimation of the phospholipid distribution in the human platelet plasma membrane based on the effect of phospholipase A2 from Naja nigricollis

Human platelets in three physiological states were prepared. These states were the gel-filtered, the thrombin-induced shape-changed, and the thrombin-activated platelets. The phospholipid distributions in these three types of membrane were probed by using the basic phospholipase A2 of Naja nigricollis. This enzyme could penetrate through these membranes to hydrolyze all of their accessible phospholipids and to cause cell lysis. The hydrolytic time-courses displayed three phases. The state of platelet in each lipid hydrolytic phase was examined by: (1) measuring the leakage of lactate dehydrogenase; (2) analyzing the morphology by both scanning and transmission electron microscopy (scanning EM and transmission EM); and (3) estimating the hydrolysis of the [32P]phosphate-labeled platelets. The existence of these three hydrolytic phases may signify that the phospholipase A2 sequentially hydrolyzed its substrates in the membrane outer leaflet, in the inner one, and in the cytosol. The content and the distribution of each phospholipid class in the plasma membranes of the resting and of the shape-changed platelets were similar. These membrane surfaces consisted mainly of phosphatidylcholine (PC) and phosphatidylethanolamine (PE). Phosphatidylserine (PS) was not exposed on the surface of the shape-changed platelet. The content of each lipid class in the activated platelet membrane was 10% more than that in the resting platelet. PS was found on the activated platelet cell surface. This implies that PS is exposed only during platelet secretion.     

Three-dimensional solution structure of a curaremimetic toxin from Naja nigricollis venom: a proton NMR and molecular modeling study.

The solution conformation of toxin alpha from Naja nigricollis (61 amino acids and four disulfides), a snake toxin which specifically blocks the activity of the nicotinic acetylcholine receptor (AcChoR), has been determined using nuclear magnetic resonance spectroscopy and molecular modeling. The solution structures were calculated using 409 distance and 73 dihedral angle restraints. The average atomic rms deviation between the eight refined structures and the mean structure is approximately 0.5 A for the backbone atoms. The overall folding of toxin alpha consists of three major loops which are stabilized by three disulfide bridges and one short C terminal loop stabilized by a fourth disulfide bridge. All the disulfides are grouped in the same region of the molecule, forming a highly constrained structure from which the loops protrude. As predicted, this structure appears to be very similar to the 1.4-A resolution crystal structure of another snake neurotoxin, namely, erabutoxin b from Laticauda semifasciata. The atomic rms deviation for the backbone atoms between the solution and crystal structures is approximately 1.7 A. The minor differences which are observed between the two structures are partly related to the deletion of one residue from the chain of toxin alpha. It is notable that, although the two toxins differ from each other by 16 amino acid substitutions, their side chains have an essentially similar spatial organization. However, most of the side chains which constitute the presumed AcChoR binding site for the curaremimetic toxins are poorly resolved in toxin alpha.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of a novel family of proteins in snake venoms. Purification and structural characterization of nawaprin from Naja nigricollis snake venom

The three-dimensional structure of nawaprin has been determined by nuclear magnetic resonance spectroscopy. This 51-amino acid residue peptide was isolated from the venom of the spitting cobra, Naja nigricollis, and is the first member of a new family of snake venom proteins referred to as waprins. Nawaprin is relatively flat and disc-like in shape, characterized by a spiral backbone configuration that forms outer and inner circular segments. The two circular segments are held together by four disulfide bonds, three of which are clustered at the base of the molecule. The inner segment contains a short antiparallel beta-sheet, whereas the outer segment is devoid of secondary structures except for a small turn or 310 helix. The structure of nawaprin is very similar to elafin, a human leukocyte elastase-specific inhibitor. Although substantial parts of the nawaprin molecule are well defined, the tips of the outer and inner circular segments, which are hypothesized to be critical for binding interactions, are apparently disordered, similar to that found in elafin. The amino acid residues in these important regions in nawaprin are different from those in elafin, suggesting that nawaprin is not an elastase-specific inhibitor and therefore has a different function in the snake venom.     

Cleavage of the A alpha-chain of fibrinogen and the alpha-polymer of fibrin by the venom of spitting cobra (Naja nigricollis)

The effect of Naja nigricollis venom of fibrinogen and highly crosslinked fibrin was examined by SDS-polyacrylamide gel electrophoresis of the reduced products of venom treatment. The venom contains a proteolytic activity which degraded the A alpha-chain of fibrinogen, but had no apparent effect on the B beta- or gamma-chains of the molecule. The venom also readily degraded the alpha-polymer or highly crosslinked fibrin, without apparent cleavage of the beta-chain or the gamma-dimer of fibrin. The venom had no observed effect on plasminogen, indicating that the effects on the A alpha-chain and the alpha-polymer are by direct action of the venom, and not due to activation of plasminogen. The fibrinogenolysis was inhibited by EDTA or 1,10-phenanthroline. Inhibition with EDTA could be reversed by the addition of Zn2+. The fibrinogenolysis was optimal between pH 7 and 8, consistent with the expected pH optimum for a Zn2+ metalloproteinase.