Goyal Sukriti, Grover Sonam, Dhanjal Jaspreet Kaur, Goyal Manisha, Tyagi Chetna, Chacko Sajeev, Grover Abhinav
Apaji Institute of Mathematics & Applied Computer Technology, Banasthali University, Tonk, Rajasthan, India, 304022.
J Mol Model. 2014 Mar;20(3):2099. doi: 10.1007/s00894-014-2099-6. Epub 2014 Feb 25.
Leishmaniasis is an endemic disease caused by infection with one of several different species of protozoan parasite Leishmania. Oligopeptidase B (OPB) is a serine peptidase which plays a vital role in survival of the Leishmania parasite in the host (human) macrophage and help in attaining complete virulence. Inhibition of this peptidase would check the parasite growth inside the host organism and would thus control its infection. Lack of efficient and cheap drugs has led to an urgent need for development of new anti-leishmanial drugs and this study is a step forward in this direction. Using a structure-based approach we virtually screened a large naturally-occurring compound library against OPB and subjected two top scoring compounds with high binding affinity to molecular dynamics simulations which showed a stable RMSD trajectory. The first compound COP (Glide score: -13.183) was found stable for 15 ns at RMSD of 2.5 Å while the second compound TOA (Glide score: -10.308) was stable for 8 ns at RMSD of 1.5 Å. The screened compounds interacted with some crucial residues of OPB such as COP interacted with Ser577 and His697 (part of the catalytic triad), Tyr499 (responsible for substrate stability), Arg576 (conserved in protozoan family) and Arg664 (plays a role in stabilization of the bound inhibitor). TOA also interacted with Glu669 (conserved in protozoan family) in addition to the residues interacted with COA. These interactions are crucial for OPB inhibition. This study identified naturally-occurring compound leads against OPB with good binding affinity and low toxicity to human cells.
利什曼病是一种由感染几种不同种类的原生动物寄生虫利什曼原虫中的一种引起的地方病。寡肽酶B(OPB)是一种丝氨酸肽酶,在利什曼原虫寄生于宿主(人类)巨噬细胞的过程中起着至关重要的作用,并有助于其达到完全毒力。抑制这种肽酶将抑制寄生虫在宿主体内的生长,从而控制其感染。由于缺乏高效且廉价的药物,迫切需要开发新的抗利什曼病药物,而本研究朝着这个方向迈出了一步。我们采用基于结构的方法,对一个大型天然化合物库进行虚拟筛选,以筛选针对OPB的化合物,并对两种具有高结合亲和力的得分最高的化合物进行分子动力学模拟,结果显示出稳定的均方根偏差(RMSD)轨迹。第一种化合物COP(Glide评分:-13.183)在均方根偏差为2.5 Å时,在15纳秒内保持稳定,而第二种化合物TOA(Glide评分:-10.308)在均方根偏差为1.5 Å时,在8纳秒内保持稳定。筛选出的化合物与OPB的一些关键残基相互作用,例如COP与Ser577和His697(催化三联体的一部分)、Tyr499(负责底物稳定性)、Arg576(在原生动物家族中保守)和Arg664(在结合抑制剂的稳定中起作用)相互作用。除了与COP相互作用的残基外,TOA还与Glu669(在原生动物家族中保守)相互作用。这些相互作用对于OPB的抑制至关重要。本研究确定了针对OPB的具有良好结合亲和力且对人类细胞毒性低的天然化合物先导物。
