多芳基取代咪唑的合成及其逆转多药耐药性研究

合成了一系列新的多芳基取代咪唑类化合物,其结构经元素分析、IR、¹HNMR和MS等确定,并采用MTT法测定了它们对由P-糖蛋白(P-gp)介导的肿瘤多药耐药性(MDR)的逆转效果.结果表明,化合物和具有很好的体外逆转MDR活性     

基于报告基因技术的MDR1转录抑制剂高通量筛选模型的建立和应用

MDR1基因是引起肿瘤多药耐药的主要基因,其编码的P-gp蛋白可持续将药物由胞内排出胞外以降低胞内药物浓度导致多药耐药,MDR1基因的转录抑制剂可抑制MDR1基因在癌细胞中的表达,从而逆转肿瘤多药耐药.通过克隆MDR1基因的启动子,将其插入pGL3-basic质粒构建MDR1-luc＋报告基因载体,再将重组载体转染入HepG2肝癌细胞并筛选单克隆细胞株,构建了MDR1启动子的高通量筛选模型,Z′因子为0.75;通过对中药样品库的筛选,得到两种中药提取物高良姜水提物、红豆蔻醇提物有明显耐药逆转效果,EC50值分别为高良姜水提物16.37mgL-1和红豆蔻醇提物14.96mgL-1,RT-PCR验证上述两种阳性样品具有明显的抑制MDR1基因表达的作用.以上结果为MDR1基因的转录抑制剂高通量筛选奠定了基础.     

柴胡逆转肝细胞癌多药耐药作用与相关机制的研究

选用对VCR天然耐药肝癌细胞株Bel-7402为对象来研究柴胡逆转MDR效果与相关的机制,以寻找一种新型的具有多药耐药逆转活性的中药.结果表明,柴胡具有逆转肝细胞癌多药耐药作用,并与抗癌药物VCR有协同作用.柴胡对人肝癌Bel-7402细胞株具有多药耐药逆转作用,提高了耐药细胞内的VCR含量,增加了VCR对细胞G2期阻滞作用,抑制了P-170糖蛋白的表达,抑制MDR1/mRNA的表达,提高了TopoαmRNA水平.     

新型紫杉烷类衍生物的制备及生物活性评价

多药耐药性问题是导致第一代紫杉烷药物在临床化疗失败的主要原因。本文对紫杉醇C7、C10、C14、C3′多个位点的取代基进行改造,针对合成的6个新型的紫杉烷化合物,在体外考察其对多药耐药肿瘤细胞株以及人结肠癌HCT-116干细胞的增殖抑制活性,实验结果表明6个化合物的抗多药耐药活性均优于紫杉醇。采用P-gp高表达的犬肾细胞MDCK-MDR1进一步研究高活性候选化合物JT-3与P-gp的相互作用。以此研发抗多药耐药型的新一代紫杉烷类药物,对开发扩大抗癌新适应症的新一代紫杉烷类抗癌药意义重大。     

新型哌啶-查尔酮类衍生物的设计、合成及抗宫颈癌和逆转顺铂耐药活性

本文采用活性亚结构拼接原理,设计并合成了15个新型含哌啶的查尔酮类衍生物,利用¹H NMR、¹³C NMR和HR-MS对结构进行表征,并初步评价了其抗宫颈癌和抗顺铂耐药宫颈癌活性作用。结果表明,化合物6g具有一定的抗肿瘤活性和逆转顺铂耐药作用;并采用Elisa法、联合顺铂用药、Western Blot和分子对接对化合物6g与VEGFR-2和P-gp靶点进行了初步的研究。本研究为基于VEGFR-2和P-gp双靶点新型分子靶向查尔酮类衍生物的设计提供了一条思路。     

新型含亲水基的噻唑烷-4-酮衍生物的合成及HIV逆转录酶抑制活性

在微波辐射条件下合成了系列C-2或N-3位含酯基的噻唑烷-4-酮衍生物,经水解或还原得到含亲水基如羧基、羟基的衍生物.化合物通过艾滋病毒逆转酶(HIV-RT)试剂盒(比色法)评价了其酶抑制活性.活性结果表明,部分化合物如8a,8b,9a,9b和14c能有效地抑制HIV逆转酶的活性.其中在N-3嘧啶环5位连有乙基的化合物8a和9a的活性最高,IC50值分别为3.02和3.06μmol·L-1.构效关系表明亲水性基团的引入对HIV逆转录酶抑制活性影响不大,而N-3位嘧啶基更有利于噻唑烷-4-酮抗HIV活性.     

联苯缩氨基胍衍生物的合成及其抗菌活性评价（英文）

基于查尔酮缩氨基胍衍生物的结构修饰,设计合成了一系列含联苯片段的缩氨基胍衍生物.目标化合物的结构通过1HNMR、13CNMR和HRMS进行了确证,并评价了其抗菌活性.结果显示目标化合物对所选菌种显示出了较好的抑制活性,最低抑菌浓度值(MIC)大都在0.5～8μg/mL.其中, 2-((4'-溴[1,1'-二苯]-4-基)亚甲基)肼-1-甲脒(3j)的抗菌活性最好,对所选菌株包括耐药菌均显示出强的抑菌活性,其中对金葡菌CMCC(B) 26003、粪肠球菌CMCC 29212和多药耐药金葡菌ATCC 33591尤为敏感,最低抑菌浓度值达到0.5μg/mL.此外,化合物3j表现低的细胞毒性,对正常人体细胞HEK293T的IC50值为60.90μmol/L.该结果表明化合物3j具有较好的选择性,在抗菌药物研究领域具有研究价值.     

抗耐药性病原菌感染以及具有多药耐药逆转活性的天然产物研究进展

综述了近年来抗耐药性病原菌感染和具有多药耐药逆转活性的天然产物的研究进展,重点介绍了这类天然产物的结构特征、生理活性和部分化合物的全合成研究.     

新型嘌呤-8-酮衍生物的合成及抗肿瘤活性研究

以2,4-二氯-5-硝基嘧啶为起始原料,通过多步反应制备了一系列新型嘌呤-8-酮衍生物,并经~1HNMR、~(13)CNMR和HRMS结构确认.采用四甲基偶氮唑盐(MTT)法测定了目标化合物的体外抗肿瘤细胞增殖活性,结果表明:部分目标化合物具有较好的抗肿瘤细胞增殖活性,其中四个化合物抑制人子宫颈癌细胞(Hela)、人急性淋巴母细胞白血病细胞(MOLT-4)和白血病细胞(K562)的活性相当或优于阳性对照药R-Roscovitine.     

含噻唑烷二酮-3-乙酸结构查尔酮衍生物的合成及抗菌活性的研究

合成了一系列含噻唑烷二酮-3-乙酸结构的新型查尔酮衍生物,并对化合物进行了抗菌活性测定.结果显示,一些化合物对4种多重耐药菌显示出较强的抗菌活性,其中化合物8g,8i,8l和8m在抗耐甲氧西林金黄色葡萄球菌的最小抑制浓度(MIC)达到4μg/mL,与对照药诺氟沙星(norfloxacin)相当.另外,在64μg/mL浓度下,所有化合物对大肠杆菌1356均无明显抑制活性.     

FG020326 sensitized multidrug resistant cancer cells to docetaxel-mediated apoptosis via enhancement of caspases activation

Apoptotic resistance is the main obstacle for treating cancer patients with chemotherapeutic drugs. Multidrug resistance (MDR) is often characterized by the expression of P-glycoprotein (P-gp), a 170-KD ATP-dependent drug efflux protein. Functional P-gp can confer resistance to activate caspase-8 and -3 dependent apoptosis induced by a range of different stimuli, including tumor necrosis and chemotherapeutic drugs such as docetaxel and vincristine. We demonstrated here that comparison of sensitive KB cells, P-gp positive (P-gp(+ve)) KBv200 cells were extremely resistant to apoptosis induced by docetaxel. FG020326, a pharmacological inhibitor of P-gp function, could enhance concentration-dependently the effect of docetaxel on cell apoptosis and sensitize caspase-8, -9 and -3 activation in P-gp overexpressing KBv200 cells, but not in KB cells. Therefore, the enhancement of caspase-8, -9 and -3 activation induced by docetaxel may be one of the key mechanisms of the reversal of P-gp mediated docetaxel resistance by FG020326.     

Reversal of Multidrug Resistance by Apolipoprotein A1-Modified Doxorubicin Liposome for Breast Cancer Treatment

Multidrug resistance (MDR) remains a major problem in cancer therapy and is characterized by the overexpression of p-glycoprotein (P-gp) efflux pump, upregulation of anti-apoptotic proteins or downregulation of pro-apoptotic proteins. In this study, an Apolipoprotein A1 (ApoA1)-modified cationic liposome containing a synthetic cationic lipid and cholesterol was developed for the delivery of a small-molecule chemotherapeutic drug, doxorubicin (Dox) to treat MDR tumor. The liposome-modified by ApoA1 was found to promote drug uptake and elicit better therapeutic effects than free Dox and liposome in MCF-7/ADR cells. Further, loading Dox into the present ApoA1-liposome systems enabled a burst release at the tumor location, resulting in enhanced anti-tumor effects and reduced off-target effects. More importantly, ApoA1-lip/Dox caused fewer adverse effects on cardiac function and other organs in 4T1 subcutaneous xenograft models. These features indicate that the designed liposomes represent a promising strategy for the reversal of MDR in cancer treatment.     

Doxorubicin Encapsulated in TPGS-Modified 2D-Nanodisks Overcomes Multidrug Resistance

Multidrug resistance (MDR) is regarded as a main obstacle for effective chemotherapy, and P-glycoprotein (P-gp)-mediated drug efflux has been demonstrated to be the key factor responsible for MDR. In this study, a novel pH-responsive hybrid drug delivery system was developed by conjugating d -α-tocopheryl polyethylene glycol 1000 succinate (TPGS), a kind of P-gp inhibitor, on the surface of laponite nanodisks to overcome MDR. The prepared LM-TPGS display excellent colloidal stability, a high encapsulation efficiency of doxorubicin (DOX), and a pH-responsive drug release profile. In vitro experiments verified that LM-TPGS/DOX could exhibit significantly enhanced therapeutic efficacy in treating DOX-resistant breast cancer cells (MCF-7/ADR) through inhibiting the activity of P-gp-mediated drug efflux and effectively accumulating DOX within cancer cells. In vivo results revealed that LM-TPGS/DOX outstandingly suppressed MCF-7/ADR tumors with low side effects. Therefore, the high drug payload, enhanced inhibition efficacy to drug-resistant cells, and low side effects make the LM-TPGS/DOX a promising nanoplatform to reverse MDR for effective chemotherapy.     

Non-alkaloids extract from Stemona sessilifolia enhances the activity of chemotherapeutic agents through P-glycoprotein-mediated multidrug-resistant cancer cells

One of the major impediments to the successful treatment of cancer is the development of resistant cancer cells, which could cause multidrug resistance (MDR), and overexpression of ABCB1/P-glycoprotein (P-gp) is one of the most common causes of MDR in cancer cells. Recently, natural products or plant-derived chemicals have been investigated more and more widely as potential multidrug-resistant (MDR) reversing agents. The current study demonstrated for the first time that non-alkaloids extract from Stemona sessilifolia significantly reversed the resistance of chemotherapeutic agents, adriamycin, paclitaxel and vincristine to MCF-7/ADR cells compared with MCF-7/S cells in a dose-dependent manner. The results obtained from these studies indicated that the non-alkaloids extract from S. sessilifolia plays an important role in reversing MDR of cancer as a P-gp modulator in vitro and may be effective in the treatment of multidrug-resistant cancers.     

In silico analysis of a few dietary phytochemicals as potential tumor chemo-sensitizers

P-glycoprotein (P-gp) is a membrane ATP-binding cassette (ABC) transporter that extrudes different xenobiotics out of cells. Besides its tissue protection role, overexpression of P-gp on the surface of many neoplastic cells restricts the cell entry of many anti-cancer drugs, the phenomenon which is known as multidrug resistance (MDR). It has been demonstrated that MDR cells can be sensitized toward anti-cancer agents when treated with P-gp inhibitors/modulators known as chemo-sensitizers. Due to the clinical significance and also considering the fact that many P-gp inhibitors are transported by P-gp, the search for more potent and low toxic non-transported chemo-sensitizers is an active area of research. Regarding this, several naturally occurring compounds were reported as MDR reversal agents, a category which is generally referred to as “fourth-generation P-gp inhibitors.” Dietary supplements containing natural products are widely used, and it is possible that they interact with co-administered pharmaceutical substances that are P-gp substrates, leading to altered pharmacokinetic profile. In silico approaches for quantitative and quantitative prediction of binding mechanism of dietary natural products to P-gp may be regarded as appropriate strategy in the early phase of drug discovery projects since they describe structural features of various phytochemicals for interaction with P-gp and pave the way toward alternative and novel anti-MDR scaffolds. In the present contribution, some phytochemicals of turmeric, black pepper, and green tea as commonly consumed dietary sources were subjected to systematic combined in silico analysis including molecular docking and amino acid decomposition analysis through B3LYP functional in association with 6-31G basis set. On the basis of major identified drug binding sites within P-gp internal pocket, modeled natural compounds were categorized as substrate, inhibitor, or modulator while structure binding relationship of each category was developed and elucidated.     

5-Aminolaevulinic acid-mediated photodynamic therapy in multidrug resistant leukemia cells

To verify if photodynamic therapy (PDT) could overcome multidrug resistance (MDR) when it it applied to eradicate minimal residual disease in patients with leukemia, we investigated the fluorescence kinetics of 5-aminolaevulinic acid (ALA)-induced protoporphyrin IX (PpIX) and the effect of subsequent photodynamic therapy on MDR leukemia cells, which express P-glycoprotein (P-gp), as well as on their parent cells. Evaluation of PpIX accumulation by flow cytometry showed that PpIX accumulated at higher levels in mdr-1 gene-transduced MDR cells (NB4/MDR) and at lower levels in doxorubicin-induced MDR cells (NOMO-1/ADR) than in their parent cells. A P-gp inhibitor could not increase PpIX accumulation. Measurement of extracellular PpIX concentration by fluorescence spectrometry showed that P-gp did not mediate the fluorescence kinetics of ALA-induced PpIX production. Assessment of ferrochelatase activity using high-performance liquid chromatography indicated that PpIX accumulation in drug-induced MDR cells was probably regulated by this enzyme. Assessment of phototoxicity of PDT using the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay showed that PDT was effective in NB4, NB4/MDR, NOMO-1 and NOMO-1/ADR cells, which accumulated high levels of PpIX, but not effective in K562 and K562/ADR cell lines, which accumulated relatively low levels of PpIX. These findings demonstrate that P-gp does not mediate the ALA-fluorescence kinetics, and multidrug resistant leukemia cells do not have cross-resistance to ALA-PDT.     

Effect of meta-tetra(hydroxyphenyl)chlorin (mTHPC)-mediated photodynamic therapy on sensitive and multidrug-resistant human breast cancer cells

Meta-tetra(hydroxyphenyl)chlorin (mTHPC) is in clinical trials for the photodynamic therapy (PDT) of localized-stage cancer. The PDT susceptibility of cells expressing multidrug resistance (MDR) phenotype is an attractive possibility to overcome the resistance to cytotoxic drugs observed during cancer chemotherapy. The accumulation, photocytotoxicity and intracellular localization of mTHPC were examined using the doxorubicin selected MCF-7/DXR human breast cancer cells, expressing P-glycoprotein (P-gp), and the wild-type parental cell line, MCF-7. No significant difference in mTHPC accumulation was observed between the two cell lines up to 3 h contact. The photodynamic activity of mTHPC, measured 24 h after irradiation with red laser light (lambda=650 nm), was significantly greater in MCF-7/DXR as compared to MCF-7 cells. A light dose of 2.5 J cm(-2) inducing 50% of cytotoxicity in MCF-7, resulted in 85% cytotoxicity in MCF-7/DXR. The presence of P-gp inhibitors SDZ-PSC-833 and cyclosporin A did not modify the mTHPC-induced cytotoxicity. The difference in intracellular mTHPC distribution pattern between two cell lines may contribute to different photocytotoxicity. Our results indicate that mTHPC mediated PDT could be useful in killing cells expressing MDR phenotype.