Abstract
Blood coagulation factor V (FV) is activated either by Factor X or thrombin, cleaving at three different sites viz., Site I (Arg709-Ser710), site II (Arg1018-Thr1019), and site III (Arg1545-Ser1546). Russell’s viper venom factor V activator (RVV-V) is a thrombin-like serine proteinase that activates FV with selective, single cleavage at site III. A long lasting effort is being pending in understanding the ‘selective’ binding specificity of the RVV-V towards site III. Here, we present the binding kinetic study of RVV-V with two designed peptides corresponding to the regions from site I (Gln699—Asn713) and site II (1008Lys—Pro1022), respectively, that include 15 amino acids. Our investigation for justifying the binding efficacy and kinetics of peptides includes SPR method, protein-peptide docking, molecular dynamics simulation, and principal component analysis (PCA). Surprisingly, the SPR experiment disclosed that the Peptide II showed a lower binding affinity with KD of 2.775 mM while the Peptide I showed none. Docking and simulation of both the peptides with RVV-V engaged either rooted or shallow binding for Peptide II and Peptide I respectively. The peptide binding resulted in global conformational changes in the native fold of RVV-V, whereas the similar studies for thrombin failed to make major changes in the native fold. In support, the PCA analysis for RVV-V showed the dislocation of catalytic triad upon binding both the peptides. Hence, RVV-V, a serine protease, is incompetent in cleaving these two sites. This study suggests a transition in RVV-V from the native rigid to the distorted flexible structure and paves a way to design a new peptide substrate/inhibitor.
Highlights
According to World Health Organization, snake envenomation causes the highest deaths in India every year
The present study captures the scenario of the Russell’s viper venom factor V activator (RVV-V) with the sites I and II at a molecular detail
The Surface Plasmon Resonance (SPR) binding kinetic study showed that the Peptide II exhibits a weak binding affinity and induces the conformational changes towards the RVV-V with KD of 2.775 mM and the Peptide I showed none
Summary
According to World Health Organization, snake envenomation causes the highest deaths in India (about 11000 deaths) every year. There are 200 out of 600 venomous snakes, which are lethal, and of medical importance [1, 2]. Snake venoms (Crotalidae and Viperadae) are the rich sources of snake venom serine proteases (SVSPs) with varying molecular specificity [3, 4]. The SVSPs are both pro and anticoagulant in nature and use conserved serine protease. There are no patents, products in development or marketed products to declare. This does not alter our adherence to all the PLOS ONE policies on sharing data and materials
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