Journal of Marine Science and Technology

Journal of Marine Science and Technology

Extraction and neutralization nematocyst venom of crambionella orsini jellyfish whit using of chelating Na-EDTA

Document Type : Original Manuscript

Authors
niloofar saki 1
yadollah nikpour ghanavaty 1
ahmad taghavi moghadam 2
kamal ghanemi 1
1 1. Department of Sea Chemistry, Faculty of Marine and Ocean Sciences, Khorramshahr Marine Science and Technology university, Khorramshahr
2 razi vaccine and serum research institute
10.22113/jmst.2018.47688.1812
Abstract
Jellyfish is one of the poisonous animals that causing human poisoning. Found a variety of jellyfish in the Persian Gulf. Although These species cant Cause of quick death in humans But they have harmful effects on human health system and have Following are the side effects. In this study extracted Crambionella Orsini Jellyfish Venom According to Bloom method and was obtained its Concentration by Biuret method and Calculated LD50 by Jung and Choi method. According to Venom concentration and its LD50 was determined that Cause of death mice 0.5 ml of venom. The use of Na-EDTA for neutralizing venom. This Chelate Was injected In two ways to mice that In both methods, Prevented death. Na-EDTA is dedicated Chelate for Calcium excretion from body that According to nuclear calciums venom is able to separated that from Venom structure and neutralize venom.
Keywords
Na-EDTA
Crambionella Orsini
Chelating
Neutralize poison
Persian Gulf

Subjects

A. G., & Lieberman, B. S. (2007). Exceptionally preserved jellyfishes from the Middle Cambrian. PloS one, 2(10), e1121.
Ceren, C. R., & Odell, G. V. (1984). Biochemistry of spider venoms.Handbook of natural toxins.
Cohen, B. D., Spritiz, N., Lubash, G. D., & Rubin, A. L. (1959). Use of a calcium chelating agent (NaEDTA) in cardiac arrhythmias. Circulation,19(6), 918-927.
Collins, S. P., Comis, A., Marshall, M., Hartwick, R. F., & Howden, M. E. H. (1993). Monoclonal antibodies neutralizing the haemolytic activity of box jellyfish (Chironex fleckeri) tentacle extracts. Comparative Biochemistry and Physiology Part B: Comparative Biochemistry106(1), 67-70.
Crisponi, G., Nurchi, V. M., Lachowicz, J. I., Crespo-Alonso, M., Zoroddu, M. A., & Peana, M. (2015). Kill or cure: Misuse of chelation therapy for human diseases. Coordination Chemistry Reviews284, 278-285.
Daly, M., Brugler, M. R., Cartwright, P., Collins, A. G., Dawson, M. N., Fautin, D. G., ... & Romano, S. L. (2007). The phylum Cnidaria: a review of phylogenetic patterns and diversity 300 years after Linnaeus.
Endean, R., Duchemin, C., McColm, D., & Fraser, E. H. (1969). A study of the biological activity of toxic material derived from nematocysts of the cubomedusan Chironex fleckeri. Toxicon6(3), 179-204.
Fujii, H., Kurahshi, T., cong, Z., Ohtsuki, A., Wang, C. and Tanizawa, M., 2011. Structure-Function relationship of metalloproteins. Annual Review. 80–81.
Hadavand, 1393. Extraction and identification of the Ghetto Seaweed Nematocytic Poison. Marine Science and Technology University of Khorramshahr. MSc Thesis. P. 56
Haddock, S. H. D., & Case, J. F. (1999). Bioluminescence spectra of shallow and deep-sea gelatinous zooplankton: ctenophores, medusae and siphonophores. Marine Biology133(3), 571-582.
Holstein, T. and Tardent, P., 1984. An ultrahigh-speed analysis of exocytosis: nematocyst discharge. Science, 223 (4638): 830–833.
Houck, H. E., Lipsky, M. M., Marzella, L., & Burnett, J. V. (1996). Toxicity of sea nettle (Chrysaora quinquecirrha) fishing tentacle nematocyst venom in cultured rat hepatocytes. Toxicon, 34(7), 771-778.
 
Hsieh, Y. P., & Rudloe, J. (1994). Potential of utilizing jellyfish as food in Western countries. Trends in Food Science & Technology5(7), 225-229.
Jung, H., & Choi, S. C. (1994). Sequential method of estimating the LD50 using a modified up-and-down rule. Journal of biopharmaceutical statistics,4(1), 19-30.
Kass-Simon G., Scappaticci A. A., 2002. The behavioral and developmental physiology of nematocysts. Canadian Journal of Zoology, 80: 1772–1794.
Kawabata, T., Lindsay, D. J., Kitamura, M., Konishi, S., Nishikawa, J., Nishida, S., ... & Nagai, H. (2013). Evaluation of the bioactivities of water-soluble extracts from twelve deep-sea jellyfish species. Fisheries Science,79(3), 487-494.
Keen, T. E. B. (1971). Comparison of tentacle extracts from Chiropsalmus quadrigatus and Chironex fleckeri. Toxicon9(3), 249-254.
Kim, E., Lee, S., Kim, J. S., Yoon, W. D., Lim, D., Hart, A. J., & Hodgson, W. C. (2006). Cardiovascular effects of Nemopilema nomurai (Scyphozoa: Rhizostomeae) jellyfish venom in rats. Toxicology letters167(3), 205-211.
Kreil, G. (1995). Hyaluronidases-a group of neglected enzymes. Protein science: a publication of the Protein Society4(9), 1666.
Laemmli, U. K. (1970). Cleavage of structural proteins during the assembly of the head of bacteriophage T4. nature227(5259), 680-685.Lee, H., Jung, E. S., Kang, C., Yoon, W. D., Kim, J. S., & Kim, E. (2011). Scyphozoan jellyfish venom metalloproteinases and their role in the cytotoxicity. Toxicon58(3), 277-284.
Mostafaei, AS, 1378. Practical and theoretical guide for protein electrophoresis in gel. Tazkeyh Publishing House, Tehran, No. 1. The first year., P. 127.
Nget-Hong, T., & Gnanajothy, P. (1992). Comparative study of the enzymatic, hemorrhagic, procoagulant and anticoagulant activities of some animal venoms. Comparative Biochemistry and Physiology Part C: Comparative Pharmacology103(2), 299-302.
Oviedo, C., & Rodríguez, J. (2003). EDTA: the chelating agent under environmental scrutiny. Quimica Nova, 26(6), 901-905.
Ozacmak, V. H., Thorington, G. U., Fletcher, W. H., & Hessinger, D. A. (2001). N-acetylneuraminic acid (NANA) stimulates in situ cyclic AMP production in tentacles of sea anemone (Aiptasia pallida): possible role in chemosensitization of nematocyst discharge. Journal of Experimental Biology204(11), 2011-2020.
Purves, W. K., Sadava, D., Orians, G. H. and Heller, H. C., 1998. Life. The Science of Biology, 4: The Evolution of Diversity. Chapter 31.
Ramasamy, S., Isbister, G. K., Seymour, J. E., & Hodgson, W. C. (2005). The in vivo cardiovascular effects of an Australasian box jellyfish (Chiropsalmus sp.) venom in rats. Toxicon45(3), 321-327.
Satterlie, R. A. (2002). Neuronal control of swimming in jellyfish: a comparative story. Canadian Journal of Zoology80(10), 1654-1669.
Takeya, H., Onikura, A., Nikai, T., Sugihara, H., & Iwanaga, S. (1990). Primary structure of a hemorrhagic metalloproteinase, HT-2, isolated from the venom of Crotalus ruber ruber. Journal of biochemistry, 108(5), 711-719.
Tibballs, J. (2006). Australian venomous jellyfish, envenomation syndromes, toxins and therapy. Toxicon48(7), 830-859.
Turner, R. J., & Freeman, S. E. (1969). Effects of Chironex fleckeri toxin on the isolated perfused guinea pig heart. Toxicon7(4), 277-286.
Waldron, K. J., Rutherford, J. C., Ford, D., & Robinson, N. J. (2009). Metalloproteins and metal sensing. Nature460(7257), 823-830.
Zezima, K., 2010, Death Does Not Deter Jellyfish Sting, The New York Times, July 22, 2010, page A11.
Zhang, Z. Q. (2011). Animal biodiversity: An introduction to higher-level classification and taxonomic richness. Zootaxa, 3148, 7-12.
Journal of Marine Science and Technology
Volume 16, Issue 2 - Serial Number 2
Autumn 2017
Pages 103-113

  • Receive Date 30 January 2016
  • Revise Date 22 February 2016
  • Accept Date 08 March 2016
  • Publish Date 23 August 2017