ANTI-DENGUE LEADS FROM CAESALPINIA BONDUC - AN IN SILICO APPROACH

Charuvil K Biju, Radha K Lekshmi, Sivanandan Sreekumar
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Abstract

Dengue (breakbone fever) is a rapidly spreading arboviral infection transmitted by Aedes mosquitoes with major public health implications in more than 100 tropical and subtropical countries mostly in Southeast Asia, South and Central America and the Western Pacific. As the virus spreads to new geographic areas, more frequent dengue outbreaks occur in different parts of the world. Fifty million cases of dengue occur worldwide each year, of which 10% require hospitalization for dengue hemorrhagic fever (DHF). It is a shocking truth that more than 90% of these are children under the age of five. The mortality rate is also significant as 2.5% die from dengue. Currently, there is no effective vaccine or specific drug for Dengue/DHF. Pharmaceutical manufacturers have turned their attention to plant-based drug candidates to produce effective drugs. Following the study investigated the active phytochemicals in the medicinal plant Caesalpinia bonduc (L.) Roxb. through docking simulation. Dengue virus non-structural protein five (NS5) and human IMPDH-II were used here as targets for docking with plant compounds. Docking results revealed that 33 compounds out of 82 phytochemicals showed better binding affinity than the native ligands of the targets. Compounds exhibiting the lowest free energy levels were further screened after studying their pharmacokinetics, medicinal chemistry friendliness, lead-likeness, and toxicity prediction to identify lead molecules. At the end of the study, three compounds, Caesaldekarin A, Caesalpinin F and Taepeenin D, which potently inhibited both targets, were selected here for further ‘in-vitro’ and ‘in-vivo’ studies.
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从 Caesalpinia Bonduc 中提取抗登革热线索--一种硅学方法
登革热(断骨热)是一种由伊蚊传播的迅速蔓延的虫媒病毒感染,对 100 多个热带和亚热带国家(主要是东南亚、南美洲、中美洲和西太平洋国家)的公共卫生有重大影响。随着病毒传播到新的地理区域,登革热在世界各地的爆发更加频繁。全世界每年发生 5 000 万例登革热病例,其中 10%需要住院治疗登革出血热(DHF)。令人震惊的是,其中 90% 以上是 5 岁以下的儿童。死亡率也很高,2.5%的人死于登革热。目前,登革热/DHF 还没有有效的疫苗或特效药。制药商已将注意力转向植物性候选药物,以生产有效的药物。本研究通过对接模拟研究了药用植物 Caesalpinia bonduc (L.) Roxb.中的活性植物化学物质。登革病毒非结构蛋白五(NS5)和人类 IMPDH-II 被用作与植物化合物对接的靶标。对接结果显示,82 种植物化合物中有 33 种化合物的结合亲和力优于靶标的原生配体。在研究了自由能水平最低的化合物的药代动力学、药物化学友好性、先导相似性和毒性预测后,进一步筛选出先导分子。最后,研究人员选择了对两个靶标都有强效抑制作用的三个化合物,即 Caesaldekarin A、Caesalpinin F 和 Taepeenin D,并在此基础上进行了进一步的 "体外 "和 "体内 "研究。
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