Unraveling the therapeutic mechanisms of myristic acid and luteolin 7-rutinoside in oral cancer: insights from network pharmacology and molecular docking analysis

Background:The compound Luteolin-7-rutinoside(L7R)is a flavone derivative of luteolin,predominantly identified in plant species belonging to the families Asteraceae.Conversely,Myristic acid is characterized by its structure as a 14-carbon,unsaturated fatty acid.In this investigation,we endeavor to elucidate the putative mechanisms underlying the therapeutic effects of Myristic Acid and Luteolin 7-rutinoside in the context of oral cancer treatment,employing network pharmacology coupled with molecular docking methodologies.Methods:The protein targets of Myristic Acid and Luteolin 7-rutinoside were identified through a search on the Swiss Target Database.Subsequently,a compound-target network was constructed using Cytoscape 3.9.1.Targets associated with OC were retrieved from the OMIM and GeneCards databases.The overlap between compound targets and OC-related targets was determined,and the resulting shared targets were subjected to protein-protein interaction(PPI)network analysis using the STRING database.Additionally,gene ontology(GO)and Kyoto Encyclopedia of Genes and Genomes(KEGG)enrichment analyses were conducted on the identified targets.Molecular docking were performed to investigate the interactions between the core target and the active compound.Results:The component target network comprises 103 nodes and 102 edges.Among the proteins in the protein-protein interaction(PPI)network,those with higher degrees are TNF,PPARG,and TP53.Analysis through Gene Ontology(GO)and Kyoto Encyclopedia of Genes and Genomes(KEGG)pathways indicates that the treatment of OC with Myristic Acid and Luteolin 7-rutinoside primarily involves the regulation of miRNA transcription and inflammatory response.The identified signaling pathways include Pathways in cancer,PPAR signaling pathway,EGFR signaling pathway,and TNF signaling pathway.Molecular docking studies reveal that Luteolin 7-rutinoside and Myristic acid exhibit higher affinity towards TNF,PPARG,TP53,and EGFR.Conclusion:This study reveals the potential molecular mechanism of Myristic Acid and Luteolin 7-rutinoside in the treatment of oral cancer,and provides a reference for subsequent basic research.

Exploring the targets and molecular mechanism of glycyrrhetinic acid against diabetic nephropathy based on network pharmacology and molecular docking

BACKGROUND Diabetic nephropathy(DN)stands as the most prevalent chronic microvascular complication of diabetes mellitus.Approximately 50%of DN patients progress to end-stage renal disease,posing a substantial health burden.AIM To employ network pharmacology and molecular docking methods to predict the mechanism by which glycyrrhetinic acid(GA)treats DN,subsequently validating these predictions through experimental means.METHODS The study initially identified GA targets using Pharm Mapper and the TCMSP database.Targets relevant to DN were obtained from the Genecards,OMIM,and TTD databases.The Venny database facilitated the acquisition of intersecting targets between GA and DN.The String database was used to construct a protein interaction network,while DAVID database was used to conducted Kyoto Encyclopedia of Genes and Genomes(KEGG)pathway analysis and Gene Ontology(GO)analysis.Molecular docking experiments were performed using Autodock software with selected proteins.Experimental validation was conducted using renal proximal tubular cells(HK-2)as the study subjects.A hyperglycemic environment was simulated using glucose solution,and the effect of GA on cell viability was assessed through the cell counting kit-8 method.Flow cytometry was employed to detect cell cycle and apoptosis,and protein immunoblot(western blot)was used to measure the expression of proteins of the phosphatidylinositol 3-kinase(PI3K)/protein kinase B(AKT)signaling pathway and insulin resistance pathway,including insulin receptor(INSR),PI3K,p-PI3K,AKT,p-AKT,and glycogen synthase kinase-3(GSK3).RESULTS A total of 186 intersecting targets between GA and DN were identified,which were associated with 144 KEGGrelated enrichment pathways,375 GO biological process entries,45 GO cellular component entries,and 112 GO cellular function entries.Molecular docking demonstrated strong binding of GA to mitogen-activated protein kinase(MAPK)-1,SRC,PIK3R1,HSP90AA1,CASPASE9,HARS,KRAS,and MAPK14.In vitro experiments revealed that GA inhibited HK-2 cell viability,induced cell cycle arrest at the G2/M phase,and reduced apoptosis with increasing drug concentration.Western blot analysis showed that GA differentially up-regulated GSK3 protein expression,up-regulated AKT/p-AKT expression,down-regulated INSR,AKT,p-AKT,PI3K,and p-PI3K protein expression,and reduced p-PI3K/PI3K levels under high glucose conditions.CONCLUSION GA may protect renal intrinsic cells by modulating the PI3K/AKT signaling pathway,thereby inhibiting HK-2 cell viability,reducing HK-2 cell apoptosis,and inducing cell cycle arrest at the G0/G1 phase.

Fluorescence Spectroscopy and Molecular Docking Approach to Probe the Interaction between Dehydroeburicoic Acid and Human Serum Albumin

The interaction between dehydroeburicoic acid (DeEA), a triterpene purified from medicinal fungi and the major transport protein, human serum albumin (HSA), were systematically studied by fluorescence spectroscopy, synchronous fluorescence spectroscopy, three-dimensional fluorescence spectroscopy and molecular docking approach under simulated physiological conditions. The intrinsic fluorescence of HSA was quenched through the combination of static and dynamic quenching mechanism. DeEA cannot be stored and carried by HSA in the body at higher temperature. The hydrogen bonding, hydrophobic force and van der Waals force were major acting forces. The site II was the major binding site. The energy transfer could occur with high probability and the binding distance was 3.29 nm. The binding process slightly changed the conformation and microenvironment of HSA. The DeEA molecule entered the hydrophobic cleft of HSA and formed the hydrogen bonding with Glu-492 and Lys-545.

Electrochemical,spectroscopic,and molecular docking studies of the interaction between the anti-retroviral drug indinavir and dsDNA

In this study,an electrochemical DNA biosensor was developed using a straightforward methodology to investigate the interaction of indinavir with calf thymus double-stranded deoxyribonucleic acid(ctdsDNA)for the first time.The decrease in the oxidation signals of deoxyguanosine(dGuo)and deoxyadenosine(dAdo),measured by differential pulse voltammetry,upon incubation with different concentrations of indinavir can be attributed to the binding mode of indinavir to ct-dsDNA.The currents of the dGuo and dAdo peaks decreased linearly with the concentration of indinavir in the range of 1.0 e10.0 mg/mL.The limit of detection and limit of quantification for indinavir were 0.29 and 0.98 mg/mL,respectively,based on the dGuo signal,and 0.23 and 0.78 mg/mL,respectively,based on the dAdo signal.To gain further insights into the interaction mechanism between indinavir and ct-dsDNA,spectroscopic measurements and molecular docking simulations were performed.The binding constant(Kb)between indinavir and ct-dsDNA was calculated to be 1.64108 M1,based on spectrofluorometric measurements.The obtained results can offer insights into the inhibitory activity of indinavir,which could help to broaden its applications.That is,indinavir can be used to inhibit other mechanisms and/or hallmarks of viral diseases.

Carbon Chain Length Determines Inhibitory Potency of Perfluoroalkyl Sulfonic Acids on Human Placental 3β-Hydroxysteroid Dehydrogenase 1:Screening,Structure-Activity Relationship,and In Silico Analysis

Objective This study aimed to compare 9 perfluoroalkyl sulfonic acids(PFSA)with carbon chain lengths(C4–C12)to inhibit human placental 3β-hydroxysteroid dehydrogenase 1(3β-HSD1),aromatase,and rat 3β-HSD4 activities.Methods Human and rat placental 3β-HSDs activities were determined by converting pregnenolone to progesterone and progesterone secretion in JEG-3 cells was determined using HPLC/MS–MS,and human aromatase activity was determined by radioimmunoassay.Results PFSA inhibited human 3β-HSD1 structure-dependently in the order:perfluorooctanesulfonic acid(PFOS,half-maximum inhibitory concentration,IC50:9.03±4.83μmol/L)>perfluorodecanesulfonic acid(PFDS,42.52±8.99μmol/L)>perfluoroheptanesulfonic acid(PFHpS,112.6±29.39μmol/L)>perfluorobutanesulfonic acid(PFBS)=perfluoropentanesulfonic acid(PFPS)=perfluorohexanesulfonic acid(PFHxS)=perfluorododecanesulfonic acid(PFDoS)(ineffective at 100μmol/L).6:2FTS(1H,1H,2H,2H-perfluorooctanesulfonic acid)and 8:2FTS(1H,1H,2H,2H-perfluorodecanesulfonic acid)did not inhibit human 3β-HSD1.PFOS and PFHpS are mixed inhibitors,whereas PFDS is a competitive inhibitor.Moreover,1–10μmol/L PFOS and PFDS significantly reduced progesterone biosynthesis in JEG-3 cells.Docking analysis revealed that PFSA binds to the steroid-binding site of human 3β-HSD1 in a carbon chain length-dependent manner.All 100μmol/L PFSA solutions did not affect rat 3β-HSD4 and human placental aromatase activity.Conclusion Carbon chain length determines inhibitory potency of PFSA on human placental 3β-HSD1 in a V-shaped transition at PFOS(C8),with inhibitory potency of PFOS>PFDS>PFHpS>PFBS=PFPS=PFHxS=PFDoS=6:2FTS=8:2FTS.

Mechanism of Wumei Pill in the Treatment of Non-Erosive reflux disease from the Perspective of Network Pharmacology and Molecular docking

Objective:Based on network pharmacology and molecular docking to explore the mechanism of Wumei Pill in the treatment of non-erosive reflux disease(NERD).Method:We collected the active ingredients and targets of Wumei Pill by Traditional Chinese Medicine Systems Pharmacology Database and Analysis Platform(TCMSP),and collected NERD related targets through Genecards,PharmGKB,Drugbank,DisGeNET,OMIM,CTD and TTD databases.Intersection targets of Wumei Pill targets and NERD related targets were the potential targets of Wumei Pill in the treatment of NERD.We imported the intersection targets into the STRING database to obtain the PPI network,and obtained the hub targets.The network diagram of"Drugs-Potential active ingredients-Potential targets"was constructed by Cytoscape 3.7.2 software.We used R software to perform Gene Ontology function enrichment analysis(GO)and Kyoto Encyclopedia of Genes and Genomes pathway enrichment analysis(KEGG)on hub targets,and then performed molecular docking verification.Results:There were 129 active ingredients and 213 drug targets of Wumei Pill of which 114 were the intersection targets.1587 GO enrichment items were identified(P<0.05),including 1,491 biological processes,11 cell components,and 85 molecular functions.143 KEGG pathways(P<0.05),mainly related to Kaposi sarcoma-associated herpesvirus infection,IL-17 signaling pathway,the TNF signaling pathway,MAPK signaling pathway.Results of molecular docking showed that the potential active ingredients in Wumei Pill had relatively stable binding activity to the key targets.Conclusion:Wumei pill for the treatment of non-erosive reflux disease are main active ingredients quercetin,kaempferol,beta sitosterol,Isocorypalmine,Stigmasterol,rutaecarpine,etc,the main targets is JUN,TP53,AKT1,may inhibit excessive inflammation,antioxidant therapy effect into full play.This provided a certain theoretical basis for clinical application.

芹菜籽中芹菜素曼尼希碱衍生物抗高尿酸血症活性研究

本文旨在探究芹菜籽中降尿酸活性成分芹菜素曼尼希碱衍生物对高尿酸血症小鼠模型的降尿酸作用及其机制。通过分子对接分析,氧嗪酸钾-酵母膏诱导高尿酸血症小鼠体内试验,探索芹菜素Mannich碱衍生物8-(4-乙基哌嗪-1-甲基)-5,7-二羟基-2-(4-苯酚)-4H-1-苯并吡喃-4-酮(APN083)的抗高尿酸血症作用。结果表明,灌胃给予高尿酸血症小鼠高、中浓度(15 mg/kg、7.5 mg/kg)APN083能明显降低血清尿酸水平(P <0.05),能显著降低血清CRE水平,具有显著的降尿酸作用,能在一定程度上抑制黄嘌呤氧化酶(XO)活性,并且促进尿酸的排泄;通过分子对接分析,该化合物通过结合到XO的活性空腔,并与周围氨基酸相互作用,从而阻碍底物分子进入活性中心,降低酶的催化活性。芹菜素曼尼希碱衍生物APN083具有较好的降尿酸作用,能从一定程度上抑制XO活性。

三味小方靶向URAT1有效成分分子对接研究

目的:以URAT1(尿酸转运蛋白1)为靶点,利用分子对接,筛选出三味小方中抑制URAT1的有效成分。方法:用AlphaFold2.1对URAT1进行建模,利用ledock软件将土茯苓、威灵仙、萆薢三味中药的组分与URAT1进行对接,并与药物苯溴马隆进行比较,筛选出活性较好的组分。结果:三味中药中有多种组分能够与URAT1活性口袋结合良好,形成多个氢键,有的还形成了π-π键。其中土茯苓苷B、恩比宁等22种组分对接打分值优于苯溴马隆。结论:三味小方中含有土茯苓苷B、恩比宁等22种分子对接结果优于苯溴马隆的组分。该药方能够抑制URAT1,降低尿酸浓度。三味中药中,土茯苓包含有效成分最多。

基于网络药理学与实验验证探讨肉桂酸治疗慢性心力衰竭的作用机制

目的采用网络药理学、分子对接及体外实验验证的方法,探讨肉桂酸治疗慢性心力衰竭(chronic heart failure,CHF)的潜在靶点及作用机制。方法通过网络药理学在线数据库预测肉桂酸靶点及CHF靶点,取交集靶点于String数据库构建蛋白互作网络,通过Cytoscape 3.7.2软件进行可视化分析,筛选出核心靶点,使用Metascape数据库进行GO和KEGG富集分析,预测肉桂酸治疗CHF的作用机制,采用分子对接技术及体外实验验证上述结果。结果网络药理学分析结果发现,肉桂酸潜在靶点187个,与6094个CHF疾病靶点相交,得到132个交集靶点,涉及CASP3、JUN、PTGS2、MMP9、TLR4等10个核心靶点。GO和KEGG富集分析显示,肉桂酸治疗CHF的作用主要与细胞对活性氧的反应、对氧化应激的反应等生物过程有关,涉及细胞凋亡等信号通路。分子对接结果显示,肉桂酸与10个核心靶点均具有良好的结合活性。体外实验结果显示,肉桂酸能显著降低心肌细胞H9c2凋亡率及活性氧水平(P<0.05),降低c-Jun、PTGS2、MMP9、TLR4 mRNA表达水平(P<0.05)和caspase-9、caspase-3、Bax蛋白表达水平(P<0.05),升高Bcl-2蛋白表达水平(P<0.05);使用乙酰半胱氨酸后,细胞凋亡率、活性氧水平及Bax蛋白表达水平显著降低(P<0.05),Bcl-2蛋白表达水平显著升高(P<0.05),与肉桂酸作用一致。结论肉桂酸能够调节多个信号靶点、抑制心肌细胞氧化应激损伤及细胞凋亡,发挥治疗CHF的作用,肉桂酸是苓桂术甘汤防治CHF的重要物质基础之一。

鞣花酸抑制酪氨酸酶的动力学、荧光光谱分析及分子对接

以蘑菇酪氨酸酶为靶点,采用抑制动力学、荧光光谱分析结合分子对接模拟技术,系统研究鞣花酸(ellagic acid,EA)对酪氨酸酶的抑制作用及机理。体外研究与动力学结果表明,EA以可逆的混合型抑制方式显著抑制酪氨酸酶活性(IC_(50)=0.05mg/mL),其结合常数K_(I)<K_(IS),表明EA与游离酶的结合比与酶-底物复合物的结合更紧密。荧光光谱猝灭分析表明,EA与酪氨酸酶存在静态猝灭作用,两者通过自发的吸热过程结合生成复合物,主要作用力为疏水作用力,只有1个或1类结合位点。同步和三维荧光光谱分析表明,EA使酪氨酸酶的微环境极性增大,疏水能力减弱,酪氨酸酶的Trp残基更靠近结合位点。分子对接模拟分析进一步印证上述实验结果,形象地表明EA对酪氨酸酶为混合型抑制,EA主要通过疏水作用力和氢键与游离酶或酶-底物复合物进行结合,最终导致酶活性降低。本研究对EA在食品工业中作为保鲜剂的各种应用具有一定参考意义。

基于网络药理学与体外实验探讨茯苓酸治疗心肌纤维化的作用机制

目的:基于网络药理学与体外验证实验探讨茯苓酸治疗心肌纤维化(myocardial fibrosis,MF)的作用机制。方法:借助SwissTargetPrediction、GeneCards等数据库预测茯苓酸、氧化应激及MF靶点,取三者交集靶点于STRING数据库构建蛋白互作(PPI)网络,借助Cytoscape 3.7.2软件进行可视化分析,筛选出核心靶点,使用Metascape数据库进行GO和KEGG富集分析,预测茯苓酸治疗MF的作用机制,采用分子对接技术及大鼠心肌成纤维细胞(cardiac fibroblasts,CFs)实验加以验证。结果:预测发现,茯苓酸潜在靶点164个、氧化应激靶点3040个、MF靶点4441个,三者交集靶点84个,涉及Bcl-2、PTGS2、Bcl-2L1、MMP-2等9个核心靶点。GO分析发现,生物过程主要作用于抗氧化活性、对缺氧的反应。KEGG分析显示,茯苓酸治疗MF的主要信号通路为PI3K/Akt。分子对接结果显示,茯苓酸与Bcl-2、PTGS2、Bcl-2L1、MMP-2等9个核心靶点均具有良好的结合活性。体外实验结果显示,茯苓酸(5、10、20μmol/L)能显著抑制CFs迁移能力(P<0.01),降低ROS、MDA水平(P<0.05),升高SOD水平(P<0.05),下调CollagenⅠ、CollagenⅢ、MMP-9、MMP-2、PTGS2 mRNA水平(P<0.05)和CollagenⅠ、CollagenⅢ、α-SMA蛋白表达(P<0.05),上调PI3K、Akt、Bcl-2、Bcl-2L1 mRNA水平(P<0.05)和p-PI3K、p-Akt蛋白表达(P<0.05)。采用PI3K抑制剂(LY294002)后,茯苓酸对CFs细胞中ROS、SOD、MDA、CollagenⅠ、CollagenⅢ、α-SMA、p-PI3K、p-Akt作用被逆转(P<0.05)。结论:表明茯苓酸能够抑制CFs氧化应激损伤和心肌纤维化,该作用与其调控PI3K/Akt信号通路密切相关。

脂肪酸配体通过改变过氧化物酶体增殖物激活受体γ三维构象调节RBL-2H3细胞脱颗粒

目的研究各种脂肪酸与效应细胞脱颗粒程度之间的关系。方法采用分子对接技术,将月桂酸、硬脂酸、油酸、亚油酸和α-亚麻酸作为配体与过氧化物酶体增殖物激活受体γ(peroxisome proliferators-activated receptorγ,PPARγ)对接,预测其对效应细胞脱颗粒的影响。基于RBL-2H3模型,以β-氨基己糖苷酶的释放量来评估这些脂肪酸能否作为PPARγ的天然配体,调节效应细胞脱颗粒。结果5种脂肪酸对RBL-2H3脱颗粒有不同影响。月桂酸显著促进脱颗粒,而油酸和α-亚麻酸抑制脱颗粒程度。硬脂酸和亚油酸则对脱颗粒程度无显著影响。结论脂肪酸作为天然配体,不同的结合深度,使PPARγ呈现出不同的三维构象,从而产生对激活因子和抑制因子不同的亲和力,以调节肥大细胞或嗜碱性粒细胞脱颗粒的程度。这为通过饮食干预来改善食物过敏提供了可能性。

基于网络药理学和分子对接技术探究川芎抗肝纤维化的作用机制

为探究川芎抗肝纤维化的活性成分及作用机制。本研究采用网络药理学方法,采用GEO数据库及DisGeNET数据库检索获取肝纤维化靶点;利用TCMSP数据库及文献检索获取川芎化学成分及作用靶点;将川芎药物靶点与疾病靶点取交集,并进行蛋白互作网络构建及拓扑分析;采用DAVID数据库进行GO和KEGG富集分析,利用微生信进行做图;通过Cytoscape软件构建“成分-靶点-信号通路”调控网络。采用分子对接技术针对川芎活性成分和关键靶点进行对接模拟。结果表明,TCMSP数据库检索结合文献研究,筛选得到川芎中8个活性成分及对应的88个作用靶点;GEO数据库筛选及DisGeNET数据库检索获取疾病靶点2038个,交集得到32个川芎治疗肝纤维化的共同靶点,并筛选出转录激活因子3(Signal transducer and activator of transcription 3,STAT3)、前列腺素内过氧化物合成酶2(Recombinant prostaglandin endoperoxide synthase 2,PTGS2)和表皮生长因子受体(Epidermal growth factor receptor,EGFR)等关键靶点。富集分析表明,川芎治疗肝纤维化的靶点主要参与肝癌信号通路、脂质代谢和动脉粥样硬化、白介素17信号通路和内分泌抵抗等信号通路,涉及RNA聚合酶Ⅱ启动子转录的正向调节过程和信号转导过程等生物学过程。“成分-靶点-信号通路”分析表明,川芎抗肝纤维化活性成分6个,分别为阿魏酸(Ferulic acid,FA)、川芎哚(Perlolyrine)、叶酸(Folic acid)、川芎萘呋内酯(Wallichilide)、亚麻油酸乙酯(Mandenol)和肉豆蔻酮(Myricanone),其中阿魏酸的节点度值最大。分子对接结果表明,川芎抗肝纤维化关键成分阿魏酸和关键靶点PTSG2、MMP9和EGFR分子均具有较好的结合能力,结合能分别为-23.04kJ/mol、-22.17kJ/mol和-25.14kJ/mol。川芎可通过靶向STAT3、PTGS2和EGFR等靶点,调控肝癌和脂质代谢等信号通路,改善肝纤维化病变,发挥保护肝脏的作用。

黄芩抗斑马鱼焦虑的作用及靶向GABA受体的分子对接研究

目的:研究黄芩50%乙醇提取物对1-(3-氯苯基)哌嗪盐酸盐(mCPP)致焦虑的斑马鱼焦虑状态的治疗作用及可能的作用机制。方法:抗焦虑研究:选取受精后10、30 d的斑马鱼分为空白组、模型组(0.1 nmol/L mCPP)、给药组(不同浓度黄芩提取物+0.1 nmol/L mCPP),Zebralab软件分析斑马鱼的平均移动距离。采用分子对接软件Autodock Vina分析黄芩中的12种主要成分与γ-氨基丁酸A型受体(GABAAR)的结合能,初步确定潜在的活性组分。结果:黄芩50%乙醇提取物对mCPP诱导的受精后10、30 d斑马鱼焦虑均有抑制作用,其中受精后30 d斑马鱼空白组、模型组(0.1 nmol/L mCPP)和给药组(200µg/mL+0.1 nmol/L mCPP)的平均移动距离分别为3633、4280、3894 mm,说明200µg/mL黄芩提取物可以减缓0.1 nmol/L mCPP对受精后30 d龄斑马鱼的焦虑行为。同时斑马鱼的焦虑行为符合趋触性。11种黄芩活性成分与GABAAR结合能强于原配体地西泮的结合能(-7.2 kcal/mol),白杨素的结合力最强(-8.8 kcal/mol),主要成分黄芩素、黄芩苷、汉黄芩素和汉黄芩苷的结合力也较强,分别为-8.3、-7.7、-8.3、-7.3 kcal/mol。预测黄芩苷等黄酮类成分是黄芩治疗焦虑主要物质基础。结论:黄芩具有抗斑马鱼焦虑的确切疗效,其活性机制可能与黄芩黄酮类成分激活GABAAR有关。

食叶草蛋白的提取工艺优化及其氨基酸分析

食叶草是一种蛋白含量较高的新食品原料,为探究食叶草蛋白的应用价值,对食叶草基本成分进行测定,采用碱提酸沉法提取食叶草蛋白,运用Box-Behnken响应面试验优化其提取工艺,并进行十二烷基硫酸钠-聚丙烯酰胺凝胶电泳(SDS-PAGE)及氨基酸组成分析。结果表明:食叶草中蛋白含量可达30.00%左右,在料液比1∶25 g/mL、提取液pH 10.0、提取温度40.0℃的条件下,食叶草蛋白提取量为101.33 mg/g;凝胶成像仪显示食叶草蛋白有3条清晰的条带,分子质量分布在55.2、40.8、15.6 kDa附近,主要集中在55.2 kDa附近;食叶草蛋白的氨基酸组成分析显示,谷氨酸、天冬氨酸含量较高,胱氨酸、蛋氨酸含量较低,必需氨基酸占总氨基酸含量的44.42%。食叶草蛋白氨基酸种类齐全且模式优良,营养价值较高,可作为人类膳食蛋白质的补充。

荷包牡丹碱对家蝇GABA受体作用机理探究

[目的]探究荷包牡丹碱对杀虫剂重要靶标GABA受体抑制机理。[方法]基于家蝇Musca domestica GABA受体亚基基因MdRdl在第3外显子(a或b)和第6外显子(c或d)交替拼接产生ac、ad、bc和bd剪接体,采用双电极电压钳技术研究荷包牡丹碱对MdRdl 4个剪接体离子电流的抑制效果,鉴定其敏感性是否与外显子交替拼接有关。并采用分子对接技术分析荷包牡丹碱与家蝇GABA受体的可能结合位点。同时,采用共刺激法验证荷包牡丹碱和GABA受体变构抑制剂溴虫氟苯双酰胺是否存在互作效应。[结果]荷包牡丹碱对MdRdlac、MdRdlbc、MdRdlad和MdRdlbd4个剪接体的IC50分别为1.274、0.948、4.702和3.698 mmol/L;对I274F突变体的IC50分别为15.46、21.67、42.83和52.33 mmol/L;与野生型剪接体相比,4个突变体IC50分别增大约11、22、8和13倍。荷包牡丹碱和溴虫氟苯双酰胺与GABA受体外显子6编码的氨基酸残基存在互作效应。[结论]第274位异亮氨酸残基为荷包牡丹碱与家蝇GABA受体互作的关键靶点,且与外显子6编码的氨基酸残基一起,具有开发协同增效作用的昆虫GABA受体别构抑制剂的潜力。

基于网络药理学、分子对接探讨熊果酸治疗缺血性脑卒中的分子机制

目的运用网络药理学、分子对接方法,挖掘熊果酸(ursolic acid,UA)治疗缺血性脑卒中的作用靶点及其潜在的分子机制。方法通过中药系统药理学数据库与分析平台及SwissTargetPrediction数据库对UA进行靶点预测,在Gene Cards数据库中获取缺血性脑卒中的靶点,并构建UA-缺血性脑卒中交叠靶点,通过String平台构建交叠靶点蛋白互作(protein-protein interaction,PPI)网络图,应用Cytoscape 3.9.1软件对PPI网络图进行拓扑属性分析,筛选出关键靶点后,进行基因本体论(gene ontology,GO)功能富集分析和京都基因与基因组百科全书(Kyoto encyclopedia of genes and genomes,KEGG)通路富集分析,最后进行靶点-UA分子对接进行验证。结果共筛选得到UA相关靶点122个和3509个缺血性脑卒中靶点;获得UA-缺血性脑卒中交叠靶点98个及19个关键靶点;其中白细胞介素-6(interleukin 6,IL-6)、肿瘤坏死因子(tumor necrosis factor,TNF)、白细胞介素-1β(interleukin 1β,IL-1β)、信号转导及转录激活因子3(signal transducers and activators of transcription,STAT3)、过氧化物酶体增殖激活受体γ(peroxisome proliferative activated receptor gamma,PPARG)是排名前5的核心靶点;KEGG通路富集分析结果显示关键靶点主要富集在血脂和动脉粥样硬化、TNF信号通路、白细胞介素17(interleukin 17,IL-17)信号通路、晚期糖基化终末产物-受体(advanced glycation end products-receptor for advanced glycation end products,AGE-RAGE)信号通路;GO功能富集分析显示关键靶点主要涉及转录因子活性、神经元凋亡过程的正向调节、炎症反应等过程;分子对接结果显示UA和排名前5的核心靶点可以稳定的结合,结合能均小于0 kcal/mol。结论UA可能通过调节IL-6、TNF、IL-1β、STAT3、PPARG影响血脂和动脉粥样硬化、TNF信号通路、IL-17信号通路、AGE-RAGE信号通路,发挥抗炎、神经保护等作用,以治疗缺血性脑卒中。

香草酸对大鼠离体肺动脉血管的舒张作用及舒张肺动脉高压大鼠体内肺动脉血管的机制

目的探讨香草酸对大鼠离体肺动脉血管的舒张作用及舒张肺动脉高压(PAH)大鼠体内肺动脉血管的机制。方法利用离体血管张力测定系统评价香草酸对大鼠离体肺小动脉血管环的舒张作用。并使用格列苯脲(GLB)、N-硝基-L-精氨酸甲酯盐酸盐(L-NAME)、4-氨基吡啶(4-AP)、吲哚美辛(IMC)、氯化钡(BaCl2)和四乙基铵(TEA)等工具药物明确香草酸舒张大鼠离体肺动脉血管的作用机制。并进一步在由野百合碱(MCT)诱导的PAH大鼠体内,利用Western Blot技术检测肺组织中与NO合成相关的蛋白质(eNOS、AMPK)的表达情况。应用HPLC技术测定大鼠肺组织中的AMP、ADP、ATP含量。采用分子对接法验证香草酸与eNOS、AMPK之间的结合情况。结果香草酸能够有效舒张由NE预收缩的血管环,EC50为137.9μmol/L。L-NAME能有效阻断香草酸的舒血管效应。体内研究显示,香草酸能有效提高MCT诱导的PAH大鼠肺组织中eNOS、AMPK蛋白的表达水平及磷酸化水平,且能够提高(ADP+AMP)/ATP。分子对接结果显示,香草酸同eNOS、AMPK的结合能分别为-6.1 kcal/mol、-6.0 kcal/mol。结论香草酸具有舒张大鼠离体肺动脉血管的作用;香草酸能够通过调节(ADP+AMP)/ATP,激活AMPK/eNOS轴,舒张PAH大鼠体内肺动脉血管,干预PAH的病理发展。

转录组学分析月桂酸单甘油酯对HepG2细胞脂代谢的调节作用

为阐明月桂酸单甘油酯(GML)调节脂代谢的具体靶点和信号通路,本研究通过GML处理油酸诱导的肝脏肿瘤细胞HepG2高脂模型,结合生物信息学预测和细胞转录组测序分析GML对肝细胞脂代谢的调节作用及其潜在靶点和机制。生物信息学分析显示:通过GML潜在靶点的GO和KEGG富集分析,分别获得信号通路519个和144条(P<0.05)。分子对接验证GML可能通过调节ALB、AKT1、EGFR等核心靶点蛋白实现其对脂代谢的调控。细胞试验结果显示:经GML干预的细胞组与高脂对照组相比,脂质积累水平有一定改善。转录组分析共筛选出2879个差异表达基因,上调和下调分别为1363个和1516个。由KEGG信号通路富集分析可知,低氧诱导因子(HIF-1α)通路和脂肪酸氧化分解代谢通路基因富集较显著,通路中重要蛋白CPT1B、FABP1等基因转录水平表达处理组比高脂组分别上升1.79倍和2.81倍,且HIF-1α调控下游主要基因表达显著上升,表明GML干预以HIF-1α通路介导改善高脂细胞氧化应激,并通过脂肪酸分解途径改善高脂细胞模型的脂代谢紊乱。本研究为探索功能性油脂成分改善高脂膳食脂代谢紊乱的作用和机制提供一定的理论参考。

纳米LDH作为藤黄酸吸附和释放载体的试验和分子对接模拟

目的 以藤黄酸(GA)为模型药物,将GA吸附在层状双金属氢氧化物(LDH)表面从而获得GA-LDH复合物。方法 采用高效液相色谱法(HPLC)测定GA含量,并进行方法学验证。采用共沉淀、离子交换、剥离-重组、胶束载药等方法制备GA-LDH复合物。以载药量和包封率为指标,对载药方法、药载比和不同粒径大小的载体进行单因素考察。采用IR和XRD等对样品结构表征,考察GA-LDH的缓冲及缓释性能;采用分子对接方法计算GA与 LDH之间的结合能大小。结果 确定以离子交换法、药载比为3∶5、水热合成LDH制备GA-LDH复合物的最佳制备工艺。优化后GA-LDH的载药量和包封率分别为21.37%、46.29%。酸碱滴定试验发现GA-LDH具有和LDH相似的缓冲性能。体外释放试验表明,GA-LDH具有一定的缓释效果,释药机制为被动扩散过程。分子对接结果从理论上佐证了GA-LDH复合物的形成。结论 该载药复合物具有良好的载药性能和缓冲性能,有望成为一种新型的中药抗肿瘤成分高效载体。