Inhibitory effects of bile acids on enzymatic and pharmacological activities of a snake venom phospholipase A(2) from group IIA

Sulfur Compounds as Inhibitors of Enzymatic Activity of a Snake Venom Phospholipase A2: Benzyl 4-nitrobenzenecarbodithioate as a Case of Study

Snakebite is a neglected disease with a high impact in tropical and subtropical countries. Therapy based on antivenom has limited efficacy in local tissue damage caused by venoms. Phospholipases A2 (PLA2) are enzymes that abundantly occur in snake venoms and induce several systemic and local effects. Furthermore, sulfur compounds such as thioesters have an inhibitory capacity against a snake venom PLA2. Hence, the objective of this work was to obtain a carbodithioate from a thioester with known activity against PLA2 and test its ability to inhibit the same enzyme. Benzyl 4-nitrobenzenecarbodithioate (I) was synthesized, purified, and characterized using as precursor 4-nitrothiobenzoic acid S-benzyl ester (II). Compound I showed inhibition of the enzymatic activity a PLA2 isolated from the venom of the Colombian rattlesnake Crotalus durissus cumanensis with an IC50 of 55.58 μM. This result is comparable with the reported inhibition obtained for II. Computational calculations were performed to support the study, and molecular docking results suggested that compounds I and II interact with the active site residues of the enzyme, impeding the normal catalysis cycle and attachment of the substrate to the active site of the PLA2.

Synthetic Inhibitors of Snake Venom Enzymes: Thioesters Derived from 2-Sulfenyl Ethylacetate

Snakebite envenomings are a global public health issue. The therapy based on the administration of animal-derived antivenoms has limited efficacy against the venom-induced local tissue damage, which often leads to permanent disability. Therefore, there is a need to find inhibitors against toxins responsible for local damage. This work aimed to synthesize thioesters derived from 2-sulfenyl ethylacetate and to evaluate the inhibitory effects on two snake venom toxins. Ethyl 2-((4-chlorobenzoyl)thio)acetate (I), Ethyl 2-((3-nitrobenzoyl)thio)acetate (II) and Ethyl 2-((4-nitrobenzoyl)thio)acetate (III) were synthesized and spectroscopically characterized. Computational calculations were performed to support the study. The inhibitory capacity of compounds (I–III) was evaluated on a phospholipase A₂ (Cdcum6) isolated from the venom of the Colombian rattlesnake Crotalus durissus cumanensis and the P-I type metalloproteinase Batx-I isolated from Bothrops atrox. I–III inhibited PLA₂ with IC₅₀ values of 193.2, 305.4 and 132.7 µM, respectively. Otherwise, compounds II and III inhibited the proteolytic activity of Batx-I with IC₅₀ of 2774 and 1879 µM. Molecular docking studies show that inhibition of PLA₂ may be due to interactions of the studied compounds with amino acids in the catalytic site and the cofactor Ca²⁺. Probably, a blockage of the hydrophobic channel and some amino acids of the interfacial binding surface of PLA₂ may occur.

Inhibitory effect of pinostrobin from Renealmia alpinia, on the enzymatic and biological activities of a PLA2

Pinostrobin is a flavanone isolated from Renealmia alpinia, a plant used in folk medicine to treat snakebites. We tested the inhibitory ability of pinostrobin on the enzymatic, anticoagulant, myotoxic and edema-inducing activities of a PLA2 isolated from Crotalus durissus cumanensis venom. The compound displayed IC50 values of 1.76mM and 1.85mM (95% Confidence intervals: 1.34-2.18 and 1.21-2.45) on the PLA2 enzymatic activity, when either aggregated or monodispersed substrates were used, respectively. When mice were injected with PLA2 preincubated with 0.4, 2.0 and 4.0mM of pinostrobin, myotoxic activity induced by the PLA2 was inhibited up to 87%. Nevertheless, these values decreased up to 56% when the pinostrobin was injected into muscle after PLA2. Pinostrobin inhibited edema-forming and anticoagulant activities of the PLA2. In order to have insights on the mode of action of pinostrobin, intrinsic fluorescence and ultraviolet studies were performed. Results suggest that pinostrobin interacts directly with the PLA2. These findings were supported by molecular docking results, which suggested that pinostrobin forms hydrogen bonds with residues His48 and Asp49 of PLA2, besides, a π-π stacking interactions with those of residues Phe5 and Trp31, and rings C of flavanone and Tyr52 of the toxin.

A facile assay to monitor secretory phospholipase A₂ using 8-anilino-1-naphthalenesulfonic acid

Secretory phospholipases A2 (sPLA2s) are present in snake venoms, serum, and biological fluids of patients with various inflammatory, autoimmune and allergic disorders. Lipid mediators in the inflammatory processes have potential value for controlling phospholipid metabolism through sPLA2 inhibition. Thus, it demands the need for screening of potential leads for sPLA2 inhibition. To date, sPLA2 activity has been assayed using expensive radioactive or chromogenic substrates, thereby limiting a large number of assays. In this study, a simple and sensitive NanoDrop assay was developed using non-fluorogenic and non-chromogenic phospholipid substrate 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC) and 8-anilino-1-naphthalenesulfonic acid (ANS) as interfacial hydrophobic probe. The modified assay required a 10ng concentration of sPLA2. ANS, as a strong anion, binds predominantly to cationic group of choline head of DMPC through ion pair formation, imparting hydrophobicity and lipophilicity and resulting in an increase in fluorescence. Triton X-100 imparts correct geometrical space during sPLA2 catalyzing DMPC, releasing lysophospholipid and acidic myristoyl acid, which in turn alters the hydrophobic environment prevailing around ANS-DMPC, which leads to weakening of the electrostatic ion pair interaction between DMPC and ANS ensuing decrease in fluorescence. These characteristic fluorescence changes between DMPC and ANS in response to sPLA2 catalysis are well documented and validated in this study.

The biflavonoid morelloflavone inhibits the enzymatic and biological activities of a snake venom phospholipase A2

The biflavonoid morelloflavone has been reported as inhibitor of secretory PLA2s (phospholipases A2 from human synovial and bee venom sources); however, its capacity to interact and inhibit snake venom PLA2 activities has not been described. In this work we tested the inhibitory ability of morelloflavone on the enzymatic, anticoagulant, myotoxic and edema-inducing activities of a PLA2 isolated from Crotalus durissus cumanensis venom. The biflavonoid displayed IC50 values of 0.48 mM (95% Confidence intervals: 0.45-0.51) and 0.38 mM (95% Confidence intervals: 0.36-0.40) on the PLA2 enzymatic activity, when either aggregated or monodispersed substrates were used, respectively. In addition, morelloflavone inhibited in a time-dependent manner and irreversibly the PLA2 enzymatic activity. When mice were injected with PLA2 preincubated (preincubation assay) with 0.13, 0.63 and 1.26 mM of the biflavonoid, the myotoxic activity induced by the PLA2 was inhibited up to 63%. Nevertheless, these values decreased up to 38% when the morelloflavone was injected into muscle after PLA2. Moreover, morelloflavone inhibited, in a concentration-dependent manner, edema-forming activity of the PLA2 in the footpad. Morelloflavone also inhibited the anticoagulant activities of the PLA2 in concentration-dependent mode. In order to have insights on the mode of action of morelloflavone, intrinsic fluorescence studies were performed. Results of these assays suggest that morelloflavone interacts directly with the PLA2. These findings were supported by molecular docking results, which suggested that morelloflavone forms hydrogen bonds with residues Gly33, Asp49, Gly53 and Thr68 of the enzyme. In addition, our results suggested a π-π stacking interaction between rings A of morelloflavone with that of the residue Tyr52, and Van der Waals interactions with Gly32, His48 and Ala56. Our molecular modeling results suggest that morelloflavone may occupy part of substrate binding cleft of the PLA2. Morelloflavone is a candidate for the development of inhibitors to be used in snakebite envenomation.