Interisland variegation of venom [Lys(49)]phospholipase A2 isozyme genes in Protobothrops genus snakes in the southwestern islands of Japan

Supramolecular Hybrids of Proteins from Habu Snake Venom with Discrete [Pt(CN)4]2- Complex

The venom of the Habu snake Protobothrops flavoviridis (P. flavoviridis) is known to contain a diverse array of proteins and peptides, with a notable presence of phospholipase A2 (PLA2) enzymes. These PLA2 enzymes have been extensively studied for their function and molecular evolution. Nevertheless, several aspects, such as the physical properties and the self-assembly mechanism of hierarchical structure from the nanoscale to the microscale with different chemical compounds, remain poorly understood. This study aims to fill this knowledge gap by investigating the behavior of enzyme components purified from P. flavoviridis venom in the presence of anionic [Pt(CN)4]2- complexes, which have the potential for soft metallophilic interactions and interesting optical properties. The purified PLA2 isozymes were diluted in Dulbecco's phosphate buffered saline (D-PBS (-)) and combined with the anionic metal complex, resulting in the formation of microstructures several micrometers in size, which further grew to form fibrous structures. This novel approach of combining PLA2 enzymes with discrete functional metal complexes opens up exciting possibilities for designing flexible and functional supramolecular and biomolecular hybrid systems in aqueous environments. These findings shed light on the potential applications of snake venom enzymes in nanotechnology and bioengineering.

Focused Proteomics Analysis of Habu Snake (Protobothrops flavoviridis) Venom Using Antivenom-Based Affinity Chromatography Reveals Novel Myonecrosis-Enhancing Activity of Thrombin-Like Serine Proteases

Snakebites are one of the major causes of death and long-term disability in the developing countries due to the presence of various bioactive peptides and proteins in snake venom. In Japan, the venom of the habu snake (Protobothrops flavoviridis) causes severe permanent damage due to its myonecrotic toxins. Antivenom immunoglobulins are an effective therapy for snakebites, and antivenom was recently developed with effective suppressive activity against myonecrosis induced by snake venom. To compare the properties of an antivenom having anti-myonecrotic activity with those of conventional antivenom with no anti-myonecrotic activity, this study applied focused proteomics analysis of habu venom proteins using 2D gel electrophoresis. As a target protein for antivenom immunoglobulins with anti-myonecrotic activity, we identified a thrombin-like serine protease, TLSP2 (TLf2), which was an inactive proteolytic isoform due to the replacement of the active site, His43 with Arg. Additionally, we identified the unique properties and a novel synergistic function of pseudoenzyme TLf2 as a myonecrosis-enhancing factor. To our knowledge, this is the first report of a function of a catalytically inactive snake serine protease.

The taxonomic position and the unexpected divergence of the Habu viper, Protobothrops among Japanese subtropical islands

There are four Habu species currently recognized in Japan: Protobothrops flavoviridis from the Amami Islands and the Okinawa Islands, P. tokarensis from the Tokara Islands, P. elegans from the Yaeyama Islands and Ovophis okinabvensis from the Amami Islands and the Okinawa Islands. To clarify their taxonomic positions, we determined the complete mitochondria genome sequence (approx. 17kb) from two specimens from two different islands each for P. flavoviridis, P. tokarensis and P. elegans as well as one specimen of O. okinavensis and reconstructed the molecular phylogeny of Protobothrops using the published sequences of related species. The maximum likelihood tree showed four major species groups within Protbothrops: Group I consisting of P. cornutus, P. dabieshanensis, P. jerdonii and P. xiangchengensis; Group II consisting of P. flavoviridis and P. tokarensis; Group III consisting of P. maolensis, P. mucrosquamatus and P. elegans; Group IV consisting of P. himalayanus and P. kaubacki. Since we observed an unexpected divergence and the paraphyly of the two samples of P. flavoviridis collected from different islands, Amami-Oshima and Okinawajima within the Group II, we expanded the analysis by increasing the number of P. flavoviridis and P. tokarensis collected from 10 islands: Amami-Oshima (5 specimens), Kakeromajima (4) and Tokunoshima (4) from the Amami Islands, Okinawajima (4), Iheyajima (4), Iejima (4), Tokashikijima (4) and Kumejima (4) from the Okinawa Islands, Kodakarajima (P. tokarensis) (4) and Takarajima (P. tokarensis) (4) from the Tokara Islands. The maximum likelihood tree of the 44 samples replicated the significant divergence of P. flavoviridis between the Amami Clade including Amami-Oshima, Kakeromajima and Tokunoshima and the Okinawa Clade including Okinawajima, Iheyajima, Iejima, Tokashikijima and Kumejima. The Amami Clade also include all specimens from the Tokara Islands currently known as an independent species, P. tokarensis, suggesting the paraphyly of the taxon, P. flavoviridis. In contrast, we observed a distinct lineage of the two specimens from the Yaeyama Islands, supporting the validity of the taxon, P. elegans as an independent species. By MCMC method, we estimated the divergence time between the Amami Clade and the Okinawa Clade to be 6.51MYA, suggesting that the vicariance of the two clades preceded the geological separation of the Amami Islands and the Okinawa Islands (∼1.5MYA). As expected from the limited mobility of terrestrial reptiles including snakes, we observed high genetic divergence in Habu mtDNA among Japanese subtropical island populations.