Venomics and antivenomics of Indian spectacled cobra (Naja naja) from the Western Ghats.

Venom proteome profiling of Naja naja from the Western Ghats region in Kerala was achieved through SDS-PAGE and RP-HPLC followed by Q-TOF LC-MS/MS analysis, incorporating PEAKS and Novor assisted de novo sequencing methodologies. A total of 115 proteins distributed across 17 different enzymatic and non-enzymatic venom protein families were identified through conventional and 39 peptides through homology-driven proteomics approaches. Fourteen peptides derived through de novo complements the Mascot data indicating the importance of homology-driven approaches in improving protein sequence information. Among the protein families identified, glutathione peroxidase and endonuclease were reported for the first time in the Indian cobra venom. Immunological cross-reactivity assessed using Indian polyvalent antivenoms suggested that VINS showed better EC50 (2.48 µg/mL) value than that of PSAV (6.04 µg/mL) and Virchow (6.03 µg/mL) antivenoms. Western blotting experiments indicated that all the antivenoms elicited poor binding specificities, especially towards low molecular mass proteins. Second-generation antivenomics studies revealed that VINS antivenom was less efficient to detect many low molecular mass proteins such as three-finger toxins and Kunitz-type serine protease Inhibitors. Taken together, the present study enabled a large-scale characterization of the venom proteome of Naja naja from the Western Ghats and emphasized the need for developing more efficient antivenoms.

Delineating the venom toxin arsenal of Malabar pit viper (Trimeresurus malabaricus) from the Western Ghats of India and evaluating its immunological cross-reactivity and in vitro cytotoxicity.

The venom protein components of Malabar pit viper (Trimeresurus malabaricus) were identified by combining SDS-PAGE and ion-exchange chromatography pre-fractionation techniques with LC-MS/MS incorporating Novor and PEAKS-assisted de novo sequencing strategies. Total 97 proteins that belong to 16 protein families such as L-amino acid oxidase, metalloprotease, serine protease, phospholipase A2, 5'-nucleotidase, C-type lectins/snaclecs and disintegrin were recognized from the venom of a single exemplar species. Of the 97 proteins, eighteen were identified through de novo approaches. Immunological cross-reactivity assessed through ELISA and western blot indicate that the Indian antivenoms binds less effectively to Malabar pit viper venom components compared to that of Russell's viper venom. The in vitro cell viability assays suggest that compared to the normal cells, MPV venom induces concentration dependent cell death in various cancer cells. Moreover, crude venom resulted in chromatin condensation and apoptotic bodies implying the induction of apoptosis. Taken together, the present study enabled in dissecting the venom proteome of Trimeresurus malabaricus and revealed the immuno-cross-reactivity profiles of commercially available Indian polyvalent antivenoms that, in turn, is expected to provide valuable insights on the need in improving antivenom preparations against its bite.

Mass spectrometry-assisted venom profiling of Hypnale hypnale found in the Western Ghats of India incorporating de novo sequencing approaches.

Hypnale hypnale (hump-nosed pit viper) is considered to be one among the medically important venomous snake species of India and Sri Lanka. In the present study, venom proteome profiling of a single Hypnale hypnale from Western Ghats of India was achieved using SDS-PAGE based protein separation followed by LC-MS/MS analysis. The identities of the proteins that were not established using the Mascot search were determined through de novo sequencing tools such as Novor followed by MS-BLAST based sequence similarity search algorithm and PEAKS proteomics software. The combined proteomics analysis revealed a total of 37 proteins belonging to nine different snake venom families, in which 7 proteins were exclusively identified through de novo strategies. The enzymatic and non-enzymatic venom protein families identified include serine proteases, metalloproteases, phospholipase A2, thrombin-like enzymes, phospholipase B, C-type lectins/snaclecs, disintegrins, cysteine rich secretory proteins and nerve growth factor. Among these, disintegrins, nerve growth factor, phospholipase B and cysteine rich secretory protein families were identified for the first time in HPV venom. This could possibly explain the regiospecific venom variation seen across snake species. Taken together, the venom proteome profiling on Indian Hypnale hypnale venom correlates with the clinical manifestations often seen in the envenomed victims.

Ethnomedicinal plants used for snake envenomation by folk traditional practitioners from Kallar forest region of South Western Ghats, Kerala, India.

BACKGROUND: The traditional medicinal systems of Indian folklore abundantly use medicinal plants or its derivatives for the treatment of snakebites. However, this traditional knowledge is on the verge of extinction, and there is an immediate necessity to conserve this oral traditional knowledge primarily by proper documentation and scientific authentication. The present ethno botanical study carried out among the folk medicine practitioners in the rural settle mental areas of Kallar forest region of southern Kerala, aims to document the folk herbal knowledge particularly for snake envenomation. MATERIALS AND METHODS: The survey was conducted during the period of June 2012-July 2013 in the rural and forest settlement areas of Kallar in the Thiruvananthapuram district of Kerala. Direct observation and oral communications with local folk medicine practitioners in this region were adopted to collect valid information regarding the herbal formulations used to treat snake bite patients. RESULTS: The study enumerates a list of 24 plant species belonging to seventeen families with anti-venomous potential. The scientific, vernacular and family names of these plants, along with the part used and their application modes are also enumerated in this communication. CONCLUSIONS: Plants are believed to be potent snake bite antidotes from centuries back, and knowledge about the use of plants is strictly conserved among tribes through generations without recorded data. It is the need of the hour to document these old drug formulations and is the cardinal responsibility of the scientific community to validate it and come up with new potent drug molecule for the benefit of snake bite victims.