肿瘤相关基因表达检测寡核苷酸芯片的制备及其初步应用

为研制肿瘤相关寡核苷酸芯片,并实现其在抗肿瘤反义核酸“癌泰得”作用机理研究方面的初步应用,制备了包含近450种肿瘤相关基因特异寡核苷酸探针的寡核苷酸芯片,建立了相应的质控标准.“癌泰得”用脂质体转染HepG2肿瘤细胞,提取细胞总RNA反转录并荧光标记cDNA,用制备的寡核苷酸芯片检测肝癌细胞HepG2的肿瘤相关基因表达水平,用软件分析获得其差异基因表达谱.0.4 μmol/L的反义核酸“癌泰得”作用于HepG2细胞15 h后,MDNCF、DHS等基因mRNA表达下调,MUC2、MPP11、LAT、HRIF-B、JNK3A1等mRNA基因表达上调,初步检测到了“癌泰得”的抗肿瘤作用可能的相关基因,为进一步的分子作用机理的探讨奠定基础.结果表明,制备的肿瘤相关芯片敏感度高、特异性高、重复性均较好,可用于检测肿瘤相关基因的表达谱,为临床诊断和基础研究提供了技术平台.     

应用RNAi文库筛选HBV复制相关基因

深入研究HBV复制机理,筛选参与HBV复制的基因,可能为开发抗乙肝病毒新药提供新 的靶点．本文拟建立一种筛选HBV复制相关基因的方法: RNAi文库感染HepG2.2.15细胞后,利用免疫磁珠收集HBsAg表达降低的细胞,提取DNA,PCR扩增siRNA编码序列,将PCR产物克隆入T-easy载体,随机挑选克隆测序,发现DDB1基因可能参与HBV复制．本试验建立了一种筛选HBV复制相关基因的方法,为大规模全基因组筛选参与HBV复制的基因奠定了基础．     

基因芯片在研究病毒感染宿主基因表达谱中的应用

人类基因组计划提供的海量基因信息以及功能基因组学理论和技术的出现,为研究病毒与宿主相互作用提供了难得的历史机遇。病毒作为一种严格的细胞内寄生物,感染宿主后会引起宿主细胞形态和功能的改变。这些变化主要由于病毒感染导致宿主细胞基因表达变化所引起。通过基因芯片技术研究病毒感染宿主的基因表达谱变化,可以发现病毒感染宿主细胞在分子水平上的应答,从而为病毒性疾病的预防、诊断和临床治疗提供新的策略。     

反基因锁核酸体外阻断乙肝病毒前S2基因表达

目的:探讨针对乙肝病毒前S2基因同聚嘌呤区的锁核酸体外抑制细胞内病毒复制的作用.方法:针对乙肝病毒前S2基因同聚嘌呤区,分别设计合成锁核酸、硫代寡核苷酸、未修饰寡核苷酸及无关对照序列,以半乳糖配体介导转染HepG2.2.15细胞,采用荧光定量聚合酶链反应技术(FQ-PCR)、时间分辨免疫荧光技术(TRFIA)和酶联免疫法(ELISA)分别监测1、3、5和7d细胞培养上清液中HBV DNA、HBsAg和前S2抗原的含量;四甲基偶氮唑蓝(MTT)法检测锁核酸对细胞代谢的影响.结果:加入锁核酸后,对HBV DNA复制、HBsAg和前S2抗原表达均显示有较强的抑制作用,且抑制率随时间呈增高趋势,7d后抑制率分别达61.56％、68.18％和72.82％.各实验组与对照组比较差异均具有统计学意义(均P＜0.05).LNA对细胞代谢无明显影响.结论:针对乙肝病毒前S2基因同聚嘌呤区的反基因锁核酸,体外能有效抑制乙肝病毒的复制,既为乙肝病毒治疗提供有效靶位,也为反基因治疗提供理论和实验依据.     

pSUPER介导的RNAi抗乙肝病毒S基因的研究

目的 研究RNAi抗乙肝病毒的作用.方法 设计并合成一段针对HBV S基因的干扰序列及一段无关的序列,克隆进pSUPER载体中,分别构建pSUPEK-HBS、pSUPEK-nonsense载体,然后将pSUPER、pSUPEK-HBS、pSUPER-nonsense转染进HepG2.2.15细胞中,用ELISA方法对细胞上清中HBsAg、HBeAg进行检测.尾静脉注射HBV转基因小鼠,取血清检测.结果 pSUPER-HBS所表达的siRNA成功的抑制了HepG 2.2.15上清及HBV转基因鼠血清中的HBsAg、HBeAg,抑制率分别达到70%、51%以及60%、42%.结论 针对HBV S区的siRNA能明显抑制HBV的复制.     

应用抑制性消减杂交技术筛选流感病毒感染宿主应答基因

从宿主系统寻找病毒感染特异性相关的生物大分子是研究病毒药物靶标和诊断标志物的新方向 .为了筛选宿主细胞中流感病毒感染特异性基因 ,采用抑制性消减杂交技术 (SSH) ,以流感病毒A 鲁防 93 9(H3N2 )感染MDCK细胞及正常MDCK细胞为材料 ,构建病毒感染特异性差减cDNA文库 ,PCR法扩增鉴定其中插入片段大小 .从差减文库中随机挑取 10 0个克隆进行测序 ,用生物信息学方法对其同源性和基因功能进行分析和预测 .结果显示 ,成功构建了流感病毒感染特异性差减cDNA文库 ,文库中cDNA片段长度在 2 5 0～ 10 0 0bp之间 .从文库中随机选取 10 0个克隆测序 ,获得了 95个有效序列 ,经blast同源性分析发现 ,大部分基因为参与宿主细胞能量代谢和蛋白质生物合成过程中的基因 ;其中 19个为无任何功能线索的新基因片段 .流感病毒感染特异性差减cDNA文库的建立和筛选出病毒感染应答候选新基因cDNA片段 ,为发现新型流感病毒药靶和诊断标志物以及病毒感染机制研究打下基础     

利用pSOS系统筛选靶向HBV病毒X基因的siRNA

构建靶向乙肝病毒(HBV)X基因的真核表达载体pSOS-X-siRNA和pSOS-siRNA,转染肝癌细胞系HepG2和HepG2.2.15,筛选和验证高效siRNA。设计4个靶向X基因siRNA,将siRNA和HBx基因插入载体pSOS得重组质粒pSOS-X-siRNA;pSOS-X-siRNA经PacI酶切去除目的片段HBx后得pSOS-siRNA。将质粒pSOS-X-siRNA和pSOS-siRNA分别转HepG2和HepG2.2.15肝癌细胞株。荧光显微镜下观察HepG2细胞绿色荧光(GFP)减弱程度预估干扰效率。ELISA检测HepG2.2.15细胞上清HBsAg、HBeAg表达,Western blotting检测胞内蛋白HBsAg、HBcAg表达,Real time PCR检测胞内HBsmRNA、HBx mRNA的转录。转染4d后,siRNA4使HepG2细胞的GFP信号表达程度最低,为阴性对照的9%,预测其干扰效果最强。siRNA4使HepG2.2.15细胞转染后4d上清的HBsAg蛋白表达为对照的(13.92±1.14)%(P0.05)、HBeAg为(21.69±4.92)%(P0.05),胞内的HBsAg、HBcAg蛋白表达量灰度比值为0.175±0.025、0.0825±0.028,均为各处理组中最低(P0.01),HBs mRNA和HBx mRNA分别降为对照的0.237±0.028(P0.01)、0.110±0.022(P0.01),差异有统计学意义,证实siRNA4为高效干扰位点。利用pSOS成功筛选并验证构建靶向HBV X基因的siRNA靶点。     

应用微阵列技术筛选PS1TP1基因转染细胞差异表达基因

阐明乙型肝炎病毒(HBV)前-S1蛋白反式激活蛋白1(PS1TP1)的表达对于肝细胞的基因表达谱的影响.应用基因芯片技术对于pcDNA3.1(-)和pcDNA3.1(-)-PS1TP1分别转染的HepG2细胞的基因表达谱进行分析.以肝癌细胞系HepG2基因作为模板,应用聚合酶链反应(PCR)技术扩增PS1TP1基因片段,以常规的分子生物学技术构建表达载体pcDNA3.1(-)-PS1TP1.以脂质体技术转染肝母细胞瘤细胞系HepG2,提取总RNA,逆转录为cDNA,与转染空白表达载体pcDNA3.1(-)的HepG2细胞进行DNA芯片分析并比较.在4096个基因表达谱的筛选中,发现有8个基因表达水平显著上调,14个基因表达水平显著下调.PS1TP1基因的表达对于肝细胞基因表达谱有显著影响.DNA芯片技术是分析反式调节靶基因的有效技术途径.     

采用基因微阵列技术对常见呼吸道病毒进行检测的初步研究

建立一种高通量的基因微阵列检测技术,对常见呼吸道病毒感染进行监控.根据公开发表的8个病毒科38种常见呼吸道病毒的序列,计算其保守区域,设计病毒的特异性检测探针,制备呼吸道病毒检测基因微阵列.利用随机引物PCR方法标记样品中的病毒靶序列,标记产物与基因微阵列上的探针杂交,清洗、扫描后进行结果分析.采用流感病毒、麻疹病毒、腮腺炎病毒和风疹病毒作为报告病毒,并对80例上呼吸道感染患者的咽拭子标本进行验证测试.初步结果表明,该呼吸道病毒微阵列基因芯片检测是可行的,在利用基因微阵列技术对病毒监控方面进行了有益的尝试,得到了有经验的信息.     

应用微阵列技术筛选PS1TP1基因转染细胞差异表达基因

阐明乙型肝炎病毒(HBV)前S1蛋白反式激活蛋白1(PS1TP1)的表达对于肝细胞的基因表达谱的影响。应用基因芯片技术对于pcDNA3.1()和pcDNA3.1()PS1TP1分别转染的HepG2细胞的基因表达谱进行分析。以肝癌细胞系HepG2基因作为模板,应用聚合酶链反应(PCR)技术扩增PS1TP1基因片段,以常规的分子生物学技术构建表达载体pcDNA3.1()PS1TP1。以脂质体技术转染肝母细胞瘤细胞系HepG2,提取总RNA,逆转录为cDNA,与转染空白表达载体pcDNA3.1()的HepG2细胞进行DNA芯片分析并比较。在4096个基因表达谱的筛选中,发现有8个基因表达水平显著上调,14个基因表达水平显著下调。PS1TP1基因的表达对于肝细胞基因表达谱有显著影响。DNA芯片技术是分析反式调节靶基因的有效技术途径。     

Differential cellular gene expression induced by hepatitis B and C viruses

Hepatitis B virus (HBV) is a hepatotropic virus that causes acute and chronic hepatocellular injury and hepatocellular carcinoma. To clarify how HBV proteins regulate host cellular gene expression, we used our in-house cDNA microarray and HepG2.2.15 cells, which are derived from HepG2 cells and produce all HBV proteins. Of 2304 genes investigated, several genes were differentially expressed in HepG2.2.15 cells compared with HepG2 cells. These genes included insulin-like growth factor II and alpha-fetoprotein, consistent with previous reports. Furthermore, we previously performed similar microarray analyses to clarify the effects of hepatitis C virus (HCV) proteins on host cells, using a HepG2-derivative cell line, which produces all HCV proteins. Using these two microarray results, we compared the differences in cellular gene expression induced by HBV and HCV proteins. The expression of the majority of genes investigated differed only slightly between HBV and HCV protein-producing cells. However, HBV and HCV proteins clearly regulated several genes in a reciprocal manner. Combined, these microarray results shed new light on the effects of HBV proteins on cellular gene expression and on the differences in the pathogenic activities of these two hepatitis viruses.     

Proteome responses to stable hepatitis B virus transfection and following interferon alpha treatment in human liver cell line HepG2

Hepatitis B virus (HBV) infection is a worldwide health problem and may develop to liver fibrosis, cirrhosis, and even hepatocellular carcinoma. To investigate the global proteome responses of liver‐derived cells to HBV infection and IFNα treatment, 2‐DE and MS‐based analysis were performed to compare the proteome changes between HBV stably transfected cell line HepG2.2.15 and its parental cell line HepG2, as well as HepG2.2.15 before and after IFNα treatment (5000 IU/mL for 72 h). Compared to HepG2, 12 of 18 down‐regulated and 27 of 32 up‐regulated proteins were identified in HepG2.2.15. After IFNα treatment, 6 of 7 down‐regulated and 11 of 14 up‐regulated proteins were identified. Differentially expressed proteins caused by HBV infection were involved with cytoskeletal matrix, heat shock stress, kinases/signal transduction, protease/proteasome components, etc. Prohibitin showed a dose‐dependent up‐regulation during IFNα treatment and might play a potent role in anti‐HBV activities of IFNα by enhancing the crossbinding p53 expression to achieve the apoptosis of HBV infected liver cells. Down‐regulation of interferon‐stimulated gene 15 (ISG15) in HepG2.2.15 and recovery by IFNα suggested its relationship with IFNα's anti‐HBV effect.     

Two-dimensional blue native/SDS-PAGE analysis reveals heat shock protein chaperone machinery involved in hepatitis B virus production in HepG2.2.15 cells

Hepatitis B virus (HBV) infection is a major health concern with more than two billion individuals currently infected worldwide. Despite the prevalence of infection, gaining a complete understanding of the molecular mechanisms of HBV infection has been difficult because HBV cannot infect common immortalized cell lines. HepG2.2.15, however, is a well established version of the HepG2 cell line that constitutively expresses HBV. Therefore, comparative proteomics analysis of HepG2.2.15 and HepG2 may provide valuable clues for understanding the HBV virus life cycle. In this study, two-dimensional blue native/SDS-PAGE was utilized to characterize different multiprotein complexes from whole cell lysates between HepG2.2.15 and HepG2. These results demonstrate that two unique protein complexes existed in HepG2.2.15 cells. When these complexes were excised from the gel and subjected to the second dimension separation and the proteins were sequenced by mass spectrometry, 20 non-redundant proteins were identified. Of these proteins, almost 20% corresponded to heat shock proteins, including HSP60, HSP70, and HSP90. Antibody-based supershift assays were used to verify the validity of the distinct protein complexes. Co-immunoprecipitation assays confirmed that HSP60, HSP70, and HSP90 proteins physically interacted in HepG2.2.15 but not HepG2 cells. We further demonstrated that down-regulation of HSP70 or HSP90 by small interfering RNA significantly inhibited HBV viral production but did not influence cellular proliferation or apoptosis. Consistent with these results, a significant reduction in HepG2.2.15 HBV secretion was observed when the HSP90 inhibitor 17-allylamino-17-demethoxygeldanamycin was used to treat HepG2.2.15 cells. Collectively these results suggest that the interaction of HSP90 with HSP70/HSP60 contributes to the HBV life cycle by forming a multichaperone machine that may constitute therapeutic targets for HBV-associated diseases.     

Fibronectin is essential for hepatitis B virus propagation in vitro: may be a potential cellular target?

Previous studies in our laboratory strongly suggested that fibronectin was upregulated by hepatitis B virus (HBV) in HepG2.2.15 cells. Report by Budkowska A also indicated that human liver fibronectin could bind HBV in a species-restricted manner. Therefore, it is reasonable to ask whether inhibiting fibronectin expression might have anti-HBV activity and whether fibronectin might be developed as a new potential cellular target for anti-HBV drugs. By using fibronectin antisense oligonucleotide (ASODN), fibronectin antibody, and Protocatechuic aldehyde (PA), we were able to show that HBV productions in HepG2.2.15 cell culture were reduced in a dose-dependent manner by fibronectin inhibition. In addition, we found that treatment with ASODNs, fibronectin antibody, and PA did not affect HepG2.2.15 cell viability. Furthermore, we observed that fibronectin inhibition sensitized HBV to anti-HBV drugs. In summary, this study demonstrates that fibronectin is essential for HBV propagation and also provides some evidences for the potential of fibronectin as a new cellular target for HBV infection therapy.     

MiR-192 inhibits nucleotide excision repair by targeting ERCC3 and ERCC4 in HepG2.2.15 cells

Deficient DNA repair capacity is associated with genetic lesions accumulation and susceptibility to carcinogenesis. MicroRNAs (miRNAs) are small non-coding RNAs that regulate various cellular pathways including DNA repair. Here we hypothesized that the existence of HBV products may interfere with cellular nucleotide excision repair (NER) through microRNA-mediated gene regulation. We found that NER was impaired in HepG2.2.15 cells, a stable HBV-expressing cell line, compared with its parental cell line HepG2. Altered miRNA expression profile, in particular the significant upregulation of miR-192, was observed in HepG2.2.15 cells. Additionally, ERCC3 and ERCC4, two key factors implicated in NER, were identified as targets of miR-192 and over-expressing miR-192 significantly inhibited cellular NER. These results indicated that persistent HBV infection might trigger NER impairment in part through upregulation of miR-192, which suppressed the levels of ERCC3 and ERCC4. It provides new insight into the effect of chronic HBV infection on NER and genetic instability in cancer.     

Antiviral effect of Phyllanthus nanus ethanolic extract against hepatitis B virus (HBV) by expression microarray analysis

Ethanolic extract of Phyllanthus nanus (P. nanus) treatment exhibited potent antiviral activity against Hepatitis B virus (HBV). The effects of these extracts on HBV in the HBV genome integrated cell lines--Alexander cells and HepG2 2.2.15 cells were examined. Experimental results showed that the ethanolic extract of P. nanus produced suppressive effect on HBsAg secretion and HBsAg mRNA expression. The extract also inhibited HBV replication as measured by HBV DNA level in vitro. In addition, using a duck HBV (DHBV) primary culture model, the P. nanus ethanolic extract suppressed viral replication of DHBV in DHBV infected primary duck hepatocytes. The gene expression pattern in Alexander cells that had been treated with the ethanolic extract of P. nanus was also revealed by microarray techniques. The microarray results indicated that there was up-regulation of expression of several genes, including annexin A7 (Axn7). The subcellular localization of Axn7 and anti-HBV effect of Axn7 over-expression in Alexander cells were also investigated. Results showed that expression of Axn7-GFP fusion protein are localized around the secretory vesicles and could cause a decrease in HBsAg secretion in Alexander cells. Axn7 protein might play an important role in the medicinal effect of the active principle(s) of P. nanus.     

Genomic analysis of anti-hepatitis B virus (HBV) activity by small interfering RNA and lamivudine in stable HBV-producing cells

Hepatitis B virus (HBV) causes acute and chronic hepatitis and hepatocellular carcinoma. Small interfering RNA (siRNA) and lamivudine have been shown to have anti-HBV effects through different mechanisms. However, assessment of the genome-wide effects of siRNA and lamivudine on HBV-producing cell lines has not been reported, which may provide a clue to interrogate the HBV-cell interaction and to evaluate the siRNA's side effect as a potential drug. In the present study, we designed seven siRNAs based on the conserved HBV sequences and tested their effects on the expression of HBV genes following sorting of siRNA-positive cells. Among these seven siRNAs, siRNA-1 and siRNA-7 were found to effectively suppress HBV gene expression. We further addressed the global gene expression changes in stable HBV-producing cells induced by siRNA-1 and siRNA-7 by use of human genome-wide oligonucleotide microarrays. Data from the gene expression profiling indicated that siRNA-1 and siRNA-7 altered the expression of 54 and 499 genes, respectively, in HepG2.2.15 cells, which revealed that different siRNAs had various patterns of gene expression profiles and suggested a complicated influence of siRNAs on host cells. We further observed that 18 of these genes were suppressed by both siRNA-1 and siRNA-7. Interestingly, seven of these genes were originally activated by HBV, which suggested that these seven genes might be involved in the HBV-host cell interaction. Finally, we have compared the effects of siRNA and lamivudine on HBV and host cells, which revealed that siRNA is more effective at inhibiting HBV expression at the mRNA and protein level in vitro, and the gene expression profile of HepG2.2.15 cells treated by lamivudine is totally different from that seen with siRNA.     

多聚嘧啶序列结合蛋白（PTB）与HBV转录后调节元件（HPRE）结合抑制HBV表面抗原的基因表达

采用RT-PCR验证PTB与HPRE在体外的特异性结合。用HepG2.2.15细胞系、HBs-HPRE瞬时转染Hela细胞探讨PTB对HBV基因表达的影响。结果显示PTB能与HPRE特异性地结合。功能性研究证明PTB可以抑制HepG2.2.15细胞的HBsAg表达量,并呈浓度依赖性。由HPRE引起的HBsAg表达的增加也能被PTB所抑制。实验数据证明PTB通过与HPRE相互作用抑制HBsAg的基因表达。     

Antisense oligonucleotides targeting abhydrolase domain containing 2 block human hepatitis B virus propagation

Hepatitis B virus (HBV) infection is a major health concern worldwide and only a minority of treated patients develop a sustained protective response following a short course of therapy, and most patients require prolonged treatment to suppress viral replication. However, several recent reports showed that inhibition of certain host cell proteins prevented viral infection, specifically the human abhydrolase domain containing 2 (ABHD2) has been confirmed by our previous study to be upregulated in HepG2.2.15 cells but downregulated by lamivudine. These observations suggested that ABHD2 was important for HBV propagation and could be a target of novel anti-HBV drugs. To assess the importance of ABHD2 to the HBV infection process, antisense oligonucleotides (ASODNs) were used to downregulate ABHD2 expression in HepG2.2.15 cells. From 5 ASODNS candidates tested, AB3 significantly downregulated ABHD2 mRNA and protein expression levels. Further, AB3 significantly reduced HBV DNA, hepatitis B surface antigen, and hepatitis B "e" antigen protein expression levels in cell medium without affecting cell viability. These results suggest that downregulation of ABHD2 using ASODNs blocked HBV replication and expression without affecting host cell physiology. Further, data demonstrated an essential role of ABHD2 in HBV propagation, suggesting it can serve as a novel target for anti-HBV drug development.