新冠病毒主蛋白酶小分子抑制剂荧光共振能量转移高通量筛选模型的优化与应用北大核心CSCD

基于荧光共振能量转移(fluorescence resonance energy transfer, FRET)原理,以新冠病毒主蛋白酶(main protease, Mpro)为靶标,建立并应用Mpro小分子抑制剂FRET高通量筛选模型,以期快速筛选新型Mpro小分子抑制剂。利用大肠杆菌原核表达与分离纯化高活性的Mpro,再以FRET法进行比活力测定。基于FRET原理,以7-甲氧基香豆素-4-乙酸(7-methoxycoumarin-4-acetic acid, MCA)与2,4-二硝基苯酚(2,4-dinitropheno, Dnp)标记的多肽作为Mpro水解底物,通过优化反应缓冲液、Mpro反应浓度、反应温度与时间及DMSO耐受浓度,建立并应用Mpro小分子抑制剂FRET高通量筛选模型进行苗头化合物的筛选。利用大肠杆菌实现了高活性Mpro的原核表达与分离纯化,且比活力不低于40 000 U/mg。通过一系列优化实验,使用0.4μmol/L Mpro与5μmol/L底物建立了Z′因子值为0.79的Mpro小分子抑制剂FRET高通量筛选模型,且反应体系中含有的二硫苏糖醇(1,4-dithiothreitol,DTT)是影响FRET筛选模型可靠性的重要因素。通过对天然产物化合物库进行高通量筛选,发现白花丹素与银杏酸在体外对Mpro酶活性具有良好的抑制作用。本研究建立了基于FRET原理的Mpro小分子抑制剂高通量筛选模型,初步证实了白花丹素与银杏酸是一类新型苗头化合物,为抗新型冠状病毒药物先导化合物的筛选与发现奠定了基础。     

新型冠状病毒主蛋白酶抑制剂的筛选方法研究进展

新型冠状病毒肺炎(coronavirus disease 2019,COVID-19)席卷全球,具有较高的传染性和死亡率,但目前尚缺乏安全有效的COVID-19疫苗与治疗药物。新型冠状病毒主蛋白酶(main protease,Mpro)的进化高度保守,在调控新冠病毒RNA复制中具有重要的生物学功能,已成为新型广谱抗冠状病毒药物开发的理想靶标之一。简便、快速、灵敏、经济的药物高通量筛选模型的建立是高选择性Mpro抑制剂高效筛选与开发的重要基础和关键技术。本文对Mpro分子结构及其抑制剂的筛选方法研究进展进行了综述和展望,以期为靶向Mpro广谱抗冠状病毒药物的筛选与开发提供有益的借鉴和参考。     

基于密码子优化策略的新型冠状病毒主蛋白酶在大肠杆菌中的表达条件优化与活性鉴定

新型冠状病毒主蛋白酶 (Main protease,Mpro) 在调控新冠病毒RNA复制中具有重要的生物学功能,且Mpro在冠状病毒中的进化高度保守并不易突变,已成为新型广谱抗冠状病毒药物开发的理想靶标之一。为了制备高纯度、高活性的Mpro,根据密码子偏爱性原则,将优化的Mpro基因分别连接到pET-21a与pET-28a表达载体中构建重组质粒。将重组质粒转化到大肠杆菌Escherichia coli Rosetta(DE3) 感受态细胞中,分别进行原核表达条件优化,所表达的重组蛋白质命名为Mpro与Mpro-28。Mpro与Mpro-28经HisTrapTM亲和层析法分离纯化后,以荧光共振能量转移 (Fluorescence resonance energy transfer,FRET) 实验进行生物学活性鉴定。FRET实验结果表明,纯化的Mpro具有良好的水解活性,Km值为11.68 μmol/L,kcat值为0.037/s,比活力不低于25 000 U/mg,约为Mpro-28的25倍,说明天然的氨基端对Mpro的生物学功能是必需的,羧基端残留的多聚组氨酸标签对其水解活性影响较小。文中基于密码子优化策略,成功地进行了新冠病毒Mpro在大肠杆菌中的表达条件优化与活性鉴定,为靶向Mpro广谱抗冠状病毒药物高通量筛选模型的建立奠定了实验基础。     

以EV71 3Cpro为靶标的抗病毒药物筛选模型的建立及抗3Cpro化合物筛选

建立一种以EV71 3C蛋白酶为靶标的抗肠病毒药物筛选模型,并应用于小分子化合物库筛选具有抗EV71活性的化合物.从临床手足口病例标本中分离肠道病毒进行PCR鉴定及基因组测序.通过插入突变在黄色荧光YFP编码框合适位点处引入EV71 3C酶切位点,构建对3C蛋白酶敏感的报告质粒pc DNA3-m YFP,然后将其与表达3C的质粒共转293A细胞,在3C抑制剂Rupintrivir存在与否的情况下通过荧光显微镜和酶标仪检测Ex(500nm)/Em(535nm)荧光信号的变化,判断建模是否成功;利用建好的筛选模型在高通量药物筛选平台对小分子化合物库进行初筛和复筛;再利用空斑分析检测筛选出的活性化合物是否对临床分离的EV71毒株具有抑制作用.m YFP在293A细胞中表达良好,3C的表达使荧光信号下降80%,Rupintrivir的存在则几乎不影响荧光表达,说明以3C为靶位的筛选模型构建成功.经过高通量初筛和复筛从26 000多种小分子化合物中获得26种能够显著回复m YFP表达的活性化合物;空斑分析显示其中2种化合物具有较为明显的抑制EV71复制的活性.因此,我们所构建的3C-m YFP共表达系统是一种简便有效的、可用于高通量筛选抗EV71 3C~(pro)药物的筛选模型.     

新型冠状病毒相关靶点小分子抑制剂虚拟筛选

为确定治疗新型冠状病毒(SARS-CoV-2)感染的候选药物,开展了针对SARS-CoV-2的药物虚拟筛选研究。以SARS-CoV-2的刺突蛋白(S蛋白)和3CL蛋白酶(主蛋白酶)作为药物靶点,以美国食品药品监督管理局(FDA)批准上市的2 726个小分子药物作为候选,通过分子对接方法,筛选出了3种(阿巴瑞克(Abarelix)、西曲瑞克(Cetrorelix)、鞣酸(Tannic acid))与S蛋白具有较强结合能力的小分子药物,1种(戈舍瑞林(Goserelin))与3CL蛋白酶具有较好结合能力的小分子药物,它们理论上都具有抑制新型冠状病毒复制的效果。将靶向3CL蛋白酶的候选药物与辉瑞公司开发的药物Paxlovid进行比较,发现其作用位点均集中于3CL蛋白酶的第130-200位的残基周围,具有相似的结合位点与相互作用。此外也对候选药物的物理与化学性质及与基因相互作用进行了分析。本研究可为开发新型冠状病毒感染的治疗药物提供参考。     

SARS冠状病毒主蛋白酶抑制剂的筛选及抑制动力学研究

对SARS冠状病毒主蛋白酶(SARS-CoV M^pro)进行异源重组表达与提纯,并以其为靶点,利用基于荧光共振能量转移(FRET)技术的体外药物筛选模型,对蛋白酶抑制剂聚焦库96种化合物进行了体外抑制活性的评价,并从动力学的角度探讨筛选出的阳性化合物对SARS-CoV M^pro的抑制能力与机制。结果表明:通过筛选获得抑制率>80%、淬灭率<20%的化合物5种,为P-1-08、P-1-19、P-2-24、P-2-28、P-2-54,其半数有效抑制浓度(IC₅₀)分别为:0.69±0.05μmol/L、1.19±0.41μmol/L、0.14±0.01μmol/L、1.36±0.07μmol/L、0.36±0.03μmol/L。其中化合物P-1-08、P-1-19、P-2-24、P-2-54对SARS冠状病毒主蛋白酶的抑制作用为不可逆抑制,化合物P-2-28的抑制作用为可逆抑制。根据Lineweaver-Burk图和Dixon图的研究,发现化合物P-2-28对SARS冠状病毒主蛋白酶呈竞争性抑制,抑制常数Ki为0.81μmol/L。通过对底物浓度,IC₅₀值及Ki值关系的研究,进一步验证了P-2-28的抑制作用为竞争性抑制。该抑制剂的发现为SARS冠状病毒主蛋白酶抑制剂的研究打下基础,为抗SARS病毒药物开发提供了先导化合物。     

一种基于绿色荧光蛋白的蛋白酶体抑制剂细胞筛选模型

为建立基于绿色荧光蛋白(GFP)的药物筛选模型,并用此模型从包括中药提取物在内的化合物中筛选新型蛋白酶体抑制剂,本研究构建了pGC-E1-ZU1-GFP融合蛋白慢病毒表达载体并感染A549细胞,筛选稳定表达细胞株,用已知蛋白酶体抑制剂PS-341处理细胞,荧光显微镜检测处理前后细胞GFP水平变化。结果获得了稳定表达pGC-E1-ZU1-GFP的A549细胞,这些细胞用PS-341处理24h后用荧光显微镜检测,发现细胞绿色荧光强度相对于对照组明显增强。利用这一模型对一些化合物进行筛查,发现了一些新的蛋白酶体抑制剂。     

以番茄斑萎病毒核蛋白为靶点的荧光偏振药物筛选体系的建立及应用

目的:基于荧光偏振技术建立靶向番茄斑萎病毒(Tomato spotted wilt virus,TSWV)核蛋白(NP)与核酸相互作用的药物筛选体系,并应用该体系展开药物筛选。方法:将目的基因克隆到pGEX-6p-1表达载体上,并采用大肠杆菌表达系统进行目的蛋白的异源表达。建立靶向TSWV NP与核酸相互作用的荧光偏振药物筛选体系,对体系的结合时间、DMSO耐受、变异性和稳定性进行研究,并展开药物筛选。结果:成功构建重组质粒pGEX-6p-1-NP,在大肠杆菌中表达并分离纯化出高质量的核蛋白。基于荧光偏振技术建立了信噪比为8∶1,Z因子为0. 82的稳定的靶向TSWV NP与核酸相互作用的药物筛选体系,并对化合物库中1 000种化合物展开药物筛选,经过初步筛选获得了1种IC_(50)为4. 15μmol/L的化合物。结论:建立了稳定的荧光偏振筛选体系,适用于靶向NP与核酸相互作用的药物的筛选。筛选到的化合物为番茄斑萎病毒的预防和控制提供参考。     

流感病毒神经氨酸酶抑制剂的筛选

以神经氨酸酶为药物靶点筛选神经氨酸酶抑制剂, 是研究和开发抗流感病毒药物的重要途径. 应用虚拟药物筛选方法, 从化合物数据库中选出部分待测化合物, 然后应用已建立的 神经氨酸酶抑制剂的高通量筛选模型, 检测了这些化合物的抑制活性, 从中发现了3个活性较高、结构新颖的化合物, 其IC50在0.1~3 μmol/L之间, 这些活性化合物的结构特点, 对于新型神经氨酸酶抑制剂的设计与开发, 将提供重要的信息指导. 流感病毒神经氨酸酶抑制剂的筛选结果表明, 虚拟筛选技术与高通量筛选技术的合理结合, 将有利于促进药物筛选与药物发现.     

以Neprilysin蛋白酶为靶标的药物筛选模型的建立及应用

目的:建立以蛋白酶Neprilysin(NEP)为靶点的高通量药物筛选模型,应用该模型筛选抑制剂。方法:利用毕赤酵母表达系统。构建重组质粒p PICZα-A-NEP,表达载体通过与酵母菌X-33基因组染色体发生同源重组,将外源基因整合于染色体后实现目的蛋白的表达。应用荧光共振能量转移法(FRET)检测蛋白酶活性,优化反应条件,建立药物筛选体系,筛选抑制剂。结果:成功构建表达载体p PICZα-A-NEP;建立了以NEP为靶标的药物筛选模型,获得模型反应动力学参数Vmax=3.6μM/s,Kcat/Km=4.5×105M-1s-1,测定模型Z-因子为0.89,说明体系稳定可用于以NEP为靶标的药物的高通量筛选;并用该模型对天然产物组分库进行筛选,在0.5mg/ml的药物浓度下,得到抑制率较高的药物为4种,并测得半数抑制浓度IC50值,其中MDCNCL01000242的IC50值最低,为(8.31±0.03)μg/ml。结论:建立的药物筛选模型较为理想,适用于NEP抑制剂的筛选,可促进药物的研发。     

Characterization of SARS-CoV main protease and identification of biologically active small molecule inhibitors using a continuous fluorescence-based assay

Severe acute respiratory syndrome associated coronavirus main protease (SARS-CoV Mpro) has been proposed as a prime target for anti-SARS drug development. We have cloned and overexpressed the SARS-CoV Mpro in Escherichia coli, and purified the recombinant Mpro to homogeneity. The kinetic parameters of the recombinant SARS-CoV Mpro were characterized by high performance liquid chromatography-based assay and continuous fluorescence-based assay. Two novel small molecule inhibitors of the SARS-CoV Mpro were identified by high-throughput screening using an internally quenched fluorogenic substrate. The identified inhibitors have Ki values at low microM range with comparable anti-SARS-CoV activity in cell-based assays.     

HIV-1整合酶链转移反应抑制剂的荧光筛选方法

整合酶被认为是抗HIV-1药物研究的理想靶点之一。为了建立便捷高效的整合酶链转移反应抑制剂筛选方法,首先将HIV-1整合酶原核表达载体pNL-IN转化入大肠杆菌感受态细胞BL21(DE3)进行原核表达,并用镍琼脂糖凝胶进行亲和纯化,获得了纯度和活性均较高的整合酶重组蛋白;然后设计了生物素标记的供体DNA和FITC标记的靶DNA,用链霉亲和素磁珠捕获反应体系中的DNA产物;最后用荧光分析仪检测DNA产物的荧光信号,并计算待测样品的抑制率。用已知整合酶抑制剂S-1360和MK-0518对筛选方法进行了验证,测定结果与已有实验数据相当,表明本筛选方法能够有效应用于HIV-1整合酶链转移反应抑制剂的筛选。与现有的整合酶链转移反应抑制剂筛选方法相比,本筛选方法步骤更为简化、耗时更短、成本更低。     

A homogeneous assay of kinase activity that detects phosphopeptide using fluorescence polarization and zinc

Homogeneous antibody-free assays of protein kinase activity have great utility in high-throughput screening in support of drug discovery. In an effort to develop such an assay, we have used a pair of fluorescein-labeled peptides of identical amino acid sequence with and without phosphorylation on serine to mimic the substrate and product, respectively, of a kinase. Using fluorescence polarization (FP), we have demonstrated that a mixture of zinc sulfate, phosphate-buffered saline, and bovine serum albumin added to the peptides dramatically and differentially increased the fluorescence polarization of the phosphorylated peptide over its nonphosphorylated derivative. A similar FP differential was observed using different peptide pairs, though the magnitude varied. The FP values obtained using this method were directly proportional to the fraction of phosphopeptide present. Therefore, an FP assay was developed using a proprietary kinase. Using this FP method, linear reaction kinetics were obtained in enzyme titration and reaction time course experiments. The IC(50) values for a panel of inhibitors of kinase activity were determined using this FP method and a scintillation proximity assay. The IC(50) values were comparable between the two methods, suggesting that the zinc FP assay may be useful as an inexpensive high-throughput assay for identifying inhibitors of kinase activity.     

Discovery of hit molecules targeting allosteric site of hepatitis C virus NS5B polymerase

Abstract

Nonstructural protein 5B (NS5B), the RNA-dependent RNA polymerase of Hepatitis C Virus (HCV), plays a key role in viral amplification and is an attractive and most explored target for discovery of new therapeutic agents for Hepatitis C. Though safe and effective, NS5B inhibitors were launched in 2013 (Sovaldi) and 2014 (Harvoni, Viekira Pak), the high price tags of these medications limit their use among poor people in developing countries. Hence, still there exists a need for cost-effective and short duration anti-HCV agents especially those targeting niche patient population who were non-respondent to earlier therapies or with comorbid conditions. The present study describes the discovery of novel non-nucleoside (NNI) inhibitors of NS5B using a series of rational drug design techniques such as virtual screening, scaffold matching and molecular docking. 2D and 3D structure based virtual screening technique identified 300 hit compounds. Top 20 hits were screened out from identified hits using molecular docking technique. Four molecules, that are representative of 20 hits were evaluated for binding affinity under in vitro conditions using surface plasmon resonance-based assay and the results emphasized that compound with CoCoCo ID: 412075 could exhibit good binding response toward NS5B and could be a potential candidate as NS5B inhibitor.

Communicated by Ramaswamy H. Sarma     

Development of a High-Throughput Fluorescence Polarization Assay to Identify Novel Ligands of Glutamate Carboxypeptidase II

Glutamate carboxypeptidase II (GCPII) is an important target for therapeutic and diagnostic interventions aimed at prostate cancer and neurologic disorders. Here we describe the development and optimization of a high-throughput screening (HTS) assay based on fluorescence polarization (FP) that facilitates the identification of novel scaffolds inhibiting GCPII. First, we designed and synthesized a fluorescence probe based on a urea-based inhibitory scaffold covalently linked to a Bodipy TMR fluorophore (TMRGlu). Next, we established and optimized conditions suitable for HTS and evaluated the assay robustness by testing the influence of a variety of physicochemical parameters (e.g., pH, temperature, time) and additives. Using known GCPII inhibitors, the FP assay was shown to be comparable to benchmark assays established in the field. Finally, we evaluated the FP assay by HTS of a 20 000-compound library. The novel assay presented here is robust, highly reproducible (Z' = 0.82), inexpensive, and suitable for automation, thus providing an excellent platform for HTS of small-molecule libraries targeting GCPII.     

A high-throughput fluorescence polarization assay for inhibitors of gyrase B

DNA gyrase, a type II topoisomerase that introduces negative supercoils into DNA, is a validated antibacterial drug target. The holoenzyme is composed of 2 subunits, gyrase A (GyrA) and gyrase B (GyrB), which form a functional A(2)B(2) heterotetramer required for bacterial viability. A novel fluorescence polarization (FP) assay has been developed and optimized to detect inhibitors that bind to the adenosine triphosphate (ATP) binding domain of GyrB. Guided by the crystal structure of the natural product novobiocin bound to GyrB, a novel novobiocin-Texas Red probe (Novo-TRX) was designed and synthesized for use in a high-throughput FP assay. The binding kinetics of the interaction of Novo-TRX with GyrB from Francisella tularensis has been characterized, as well as the effect of common buffer additives on the interaction. The assay was developed into a 21-μL, 384-well assay format and has been validated for use in high-throughput screening against a collection of Food and Drug Administration-approved compounds. The assay performed with an average Z' factor of 0.80 and was able to identify GyrB inhibitors from a screening library.     

Virtual screening for potential inhibitors of homology modeled <Emphasis Type="Italic">Leptospira interrogans</Emphasis> MurD ligase

The life-threatening infections caused by Leptospira serovars remain a global challenge since long time. Prevention of infection by controlling environmental factors being difficult to practice in developing countries, there is a need for designing potent anti-leptospirosis drugs. ATP-dependent MurD involved in biosynthesis of peptidoglycan was identified as common drug target among pathogenic Leptospira serovars through subtractive genomic approach. Peptidoglycan biosynthesis pathway being unique to bacteria and absent in host represents promising target for antimicrobial drug discovery. Thus, MurD 3D models were generated using crystal structures of 1EEH and 2JFF as templates in Modeller9v7. Structural refinement and energy minimization of the model was carried out in Maestro 9.0 applying OPLS-AA 2001 force field and was evaluated through Procheck, ProSA, PROQ, and Profile 3D. The active site residues were confirmed from the models in complex with substrate and inhibitor. Four published MurD inhibitors (two phosphinics, one sulfonamide, and one benzene 1,3-dicarbixylic acid derivative) were queried against more than one million entries of Ligand.Info Meta-Database to generate in-house library of 1,496 MurD inhibitor analogs. Our approach of virtual screening of the best-ranked compounds with pharmacokinetics property prediction has provided 17 novel MurD inhibitors for developing anti-leptospirosis drug targeting peptidoglycan biosynthesis pathway.     

Development of a fluorogenic ADAMTS-7 substrate

The extracellular protease ADAMTS-7 has been identified as a potential therapeutic target in atherosclerosis and associated diseases such as coronary artery disease (CAD). However, ADAMTS-7 inhibitors have not been reported so far. Screening of inhibitors has been hindered by the lack of a suitable peptide substrate and, consequently, a convenient activity assay. Here we describe the first fluorescence resonance energy transfer (FRET) substrate for ADAMTS-7, ATS7FP7. ATS7FP7 was used to measure inhibition constants for the endogenous ADAMTS-7 inhibitor, TIMP-4, as well as two hydroxamate-based zinc chelating inhibitors. These inhibition constants match well with IC₅₀ values obtained with our SDS-PAGE assay that uses the N-terminal fragment of latent TGF-β–binding protein 4 (LTBP4S-A) as a substrate. Our novel fluorogenic substrate ATS7FP7 is suitable for high throughput screening of ADAMTS-7 inhibitors, thus accelerating translational studies aiming at inhibition of ADAMTS-7 as a novel treatment for cardiovascular diseases such as atherosclerosis and CAD.     

A real-time fluorescence polarization activity assay to screen for inhibitors of bacterial ribonuclease P

Ribonuclease P (RNase P) is an essential endonuclease that catalyzes the 5′ end maturation of precursor tRNA (pre-tRNA). Bacterial RNase P is an attractive potential antibacterial target because it is essential for cell survival and has a distinct subunit composition compared to the eukaryal counterparts. To accelerate both structure-function studies and discovery of inhibitors of RNase P, we developed the first real-time RNase P activity assay using fluorescence polarization/anisotropy (FP/FA) with a 5′ end fluorescein-labeled pre-tRNA^Asp substrate. This FP/FA assay also detects binding of small molecules to pre-tRNA. Neomycin B and kanamycin B bind to pre-tRNA^Asp with a K_d value that is comparable to their IC₅₀ value for inhibition of RNase P, suggesting that binding of these antibiotics to the pre-tRNA substrate contributes to the inhibitory activity. This assay was optimized for high-throughput screening (HTS) to identify specific inhibitors of RNase P from a 2880 compound library. A natural product derivative, iriginol hexaacetate, was identified as a new inhibitor of Bacillus subtilis RNase P. The FP/FA methodology and inhibitors reported here will further our understanding of RNase P molecular recognition and facilitate discovery of antibacterial compounds that target RNase P.