Evaluation of Snake Venom’s PhospholipaseA2 Enzyme Inhibition Activity of Cyphostemma adenocoule

Current Chemical Biology Pub Date : 2020-12-28 DOI:10.2174/2212796814999200917114914

A. Kaushik, Teamrat S. Tesfai, Daniel K. Barkh, Furtuna K. Ghebremeskel, Habtom G. Zerihun, Saron W. Woldeab

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引用次数: 1

Abstract

A snake bite is fundamentally an injury often resulting in puncture wounds meted out by the animal's fangs and occasionally resulting in envenomation. Rate of snake bites around 5,400,000 bites per year leads to over 2,500,000 envenomings and around 125,000 fatal cases annually. Snake venom enzymes are rich in metalloproteinases, phospholipaseA2, proteinases, acetylcholinesterases and hyaluronidases. Cyphostemma adenocoule is traditionally being used for the treatment of snake bites in Eritrea. The present research was aimed at evaluating the snake venom enzyme inhibition activity of C. adenocoule against puff adder venom and developing a base for the traditional use of the plant against snakebites in Eritrea. The anti-venom activity of C. adenocoule was assessed in-vitro through phospholipaseA2 enzyme inhibition assay using egg yolk as a cell. The ethanol and chloroform extracts of C. adenocoule showed in vitro anti phospholipase A2 activity, whereas the water extracts of the plant showed no activity. Among the extracts of C. adenocoule, the highest percentage of inhibition was obtained from chloroform extract (95.55% at 100mg/ml). The extract showed prominent activity at different concentrations (34.7% at10mg/ml, 48.8% at 20mg/ml, 54.8% at 40mg/ml, 60.9% at 60mg/ml, 80.5% at 80mg /ml). The ethanol extract also showed certain activity at various concentrations (25.22% at10mg/ml, 14.78% at 20mg/ml, 2.6% at40mg/ml). The activity of the chloroform extracts increases as concentration increases, whereas the activity of the ethanol extracts decreases as concentration increases. The aqueous extract of C. adenocoule did not show any activity at all concentrations. In this study, the chloroform and ethanol extracts of the plant inhibited the enzyme of interest and thus proved the efficacy of anti-snake venom activity of the plant.

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蛇毒对草藤腺囊磷脂酶a2酶抑制活性的评价

蛇咬基本上是一种伤害，通常会导致动物的毒牙刺出伤口，偶尔会导致中毒。每年约有540万人被蛇咬伤，导致超过250万人中毒，约12.5万人死亡。蛇毒酶中含有丰富的金属蛋白酶、磷脂酶a2、蛋白酶、乙酰胆碱酯酶和透明质酸酶。在厄立特里亚，传统上使用Cyphostemma adenocoule治疗蛇咬伤。本研究旨在评价该植物对膨化蝰蛇毒液的蛇毒酶抑制活性，为该植物在厄立特里亚的传统应用奠定基础。以卵黄为细胞，通过磷脂酶a2酶抑制实验，对腺孔线虫体外抗蛇毒活性进行了评价。腺苷醇提物和氯仿提物具有抗磷脂酶A2的活性，而水提物无抗磷脂酶A2活性。其中，氯仿提取物在100mg/ml浓度下的抑菌率最高(95.55%)。提取物在不同浓度下的活性分别为:10mg/ml 34.7%、20mg/ml 48.8%、40mg/ml 54.8%、60mg/ml 60.9%、80mg /ml 80.5%。乙醇提取物在不同浓度下也表现出一定的活性(10mg/ml为25.22%，20mg/ml为14.78%，40mg/ml为2.6%)。氯仿提取物的活性随着浓度的增加而增加，而乙醇提取物的活性随着浓度的增加而降低。在所有浓度下，水提物均无活性。在本研究中，该植物的氯仿和乙醇提取物抑制了感兴趣的酶，从而证明了该植物抗蛇毒活性的有效性。

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来源期刊

Current Chemical Biology Medicine-Biochemistry (medical)

CiteScore

1.40

自引率

0.00%

发文量

期刊介绍： Current Chemical Biology aims to publish full-length and mini reviews on exciting new developments at the chemistry-biology interface, covering topics relating to Chemical Synthesis, Science at Chemistry-Biology Interface and Chemical Mechanisms of Biological Systems. Current Chemical Biology covers the following areas: Chemical Synthesis (Syntheses of biologically important macromolecules including proteins, polypeptides, oligonucleotides, oligosaccharides etc.; Asymmetric synthesis; Combinatorial synthesis; Diversity-oriented synthesis; Template-directed synthesis; Biomimetic synthesis; Solid phase biomolecular synthesis; Synthesis of small biomolecules: amino acids, peptides, lipids, carbohydrates and nucleosides; and Natural product synthesis).