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大环HIV-1灭活剂的化学优化,以提高效力并增加三唑环处的结构多样性。

Chemical optimization of macrocyclic HIV-1 inactivators for improving potency and increasing the structural diversity at the triazole ring.

作者信息

Rashad Adel A, Acharya Kriti, Haftl Ann, Aneja Rachna, Dick Alexej, Holmes Andrew P, Chaiken Irwin

机构信息

Department of Biochemistry & Molecular Biology, Drexel University College of Medicine, Philadelphia, Pennsylvania 19102, USA.

出版信息

Org Biomol Chem. 2017 Sep 26;15(37):7770-7782. doi: 10.1039/c7ob01448a.

DOI:10.1039/c7ob01448a
PMID:28770939
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5614861/
Abstract

HIV-1 entry inhibition remains an urgent need for AIDS drug discovery and development. We previously reported the discovery of cyclic peptide triazoles (cPTs) that retain the HIV-1 irreversible inactivation functions of the parent linear peptides (PTs) and have massively increased proteolytic resistance. Here, in an initial structure-activity relationship investigation, we evaluated the effects of variations in key structural and functional components of the cPT scaffold in order to produce a platform for developing next-generation cPTs. Some structural elements, including stereochemistry around the cyclization residues and Ile and Trp side chains in the gp120-binding pharmacophore, exhibited relatively low tolerance for change, reflecting the importance of these components for function. In contrast, in the pharmacophore-central triazole position, the ferrocene moiety could be successfully replaced with smaller aromatic rings, where a p-methyl-phenyl methylene moiety gave cPT 24 with an IC value of 180 nM. Based on the observed activity of the biphenyl moiety when installed on the triazole ring (cPT 23, IC ∼ 269 nM), we further developed a new on-resin synthetic method to easily access the bi-aryl system during cPT synthesis, in good yields. A thiophene-containing cPT AAR029N2 (36) showed enhanced entropically favored binding to Env gp120 and improved antiviral activity (IC ∼ 100 nM) compared to the ferrocene-containing analogue. This study thus provides a crucial expansion of chemical space in the pharmacophore to use as a starting point, along with other allowable structural changes, to guide future optimization and minimization for this important class of HIV-1 killing agents.

摘要

HIV-1进入抑制仍然是艾滋病药物研发的迫切需求。我们之前报道了环状肽三唑(cPTs)的发现,它们保留了母体线性肽(PTs)的HIV-1不可逆失活功能,并且蛋白水解抗性大幅提高。在此,在初步的构效关系研究中,我们评估了cPT支架关键结构和功能成分变化的影响,以便构建一个开发下一代cPTs的平台。一些结构元素,包括环化残基周围的立体化学以及gp120结合药效团中的Ile和Trp侧链,对变化的耐受性相对较低,这反映了这些成分对功能的重要性。相比之下,在药效团中心的三唑位置,二茂铁部分可以成功地被较小的芳香环取代,其中对甲基苯基亚甲基部分赋予cPT 24的IC值为180 nM。基于在三唑环上安装联苯部分时观察到的活性(cPT 23,IC ∼ 269 nM),我们进一步开发了一种新的树脂上合成方法,以便在cPT合成过程中以良好的产率轻松获得双芳基系统。与含二茂铁的类似物相比,含噻吩的cPT AAR029N2(36)显示出与Env gp120的熵有利结合增强,抗病毒活性提高(IC ∼ 100 nM)。因此,本研究为药效团中的化学空间提供了关键扩展,作为一个起点,连同其他允许的结构变化,以指导这类重要的HIV-1杀伤剂的未来优化和最小化。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/402e/5614861/8366a3ae5328/nihms900800f11.jpg
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