溶瘤腺病毒在肿瘤靶向治疗中的研究进展

溶瘤腺病毒是一组通过基因工程构建的腺病毒、能够选择性在肿瘤细胞中完成感染-复制周期,从而特异性地杀伤、溶解肿瘤而不伤及其他正常细胞、组织,其作用机制包括:通过基因的缺失突变、插入特异性启动子、以及通过病毒结构蛋白的修饰等方面,实现肿瘤靶向治疗作用。本文就相关研究及进展进行综述。     

构建溶瘤腺病毒的策略

溶瘤腺病毒是通过遗传工程改造的腺病毒,具有溶细胞复制周期的特性和特异靶向肿瘤细胞和裂解肿瘤细胞的功能。溶瘤腺病毒通过复制、释放子代病毒感染邻近肿瘤细胞。现在对腺病毒生活周期的认识水平,可以对其基因组进行改造从而使其特异性裂解肿瘤细胞而不杀伤正常细胞,并且构建了多种溶瘤腺病毒。本文主要概述了溶瘤腺病毒的三种构建策略:剔除腺病毒在正常细胞中复制所必需而在肿瘤细胞中不需要的某些基因;利用肿瘤特异性启动子控制病毒复制所必需的基因;对腺病毒衣壳蛋白进行基因修饰,达到特异性结合肿瘤细胞的目的。     

腺病毒携带IL-12增强抗原致敏树突细胞在肝癌基因治疗中的研究

目的:近年来通过应用白介素-12治疗肿瘤取得良好效果,因此对国内外应用腺病毒携带IL-12增强抗原致敏树突细胞在肝癌基因治疗中的研究进展进行总结,以探索更为可行治疗方法。方法:运用Pubmed、Elsevier Sciencedirect、CNKI及万方全文数据库检索系统,以腺病毒,IL-12,肝癌,树突细胞为关键词,检索2008-01至2012-11月发表的文献。纳入标准:1)IL-12的生物学特性,在抗肿瘤过程中的免疫作用,2)应用腺病毒携带IL-12对抗肝癌治疗研究,3)肿瘤抗原致敏树突细胞对肿瘤的影响。根据纳入标准分析文献26篇。结果:通过腺病毒携带IL-12可以增强肿瘤抗原致敏树突细胞的免疫应答。并通过诱导肿瘤细胞的凋亡,减少新生血管的生成而对肿瘤产生直接抑制,有效抑制肝癌的生长和转移。结论:本文通过对IL-12的生物学特征、抗肿瘤通路、作用机制及在腺病毒介导下肿瘤抗原致敏树突细胞研究进展的概述,为腺病毒携带IL-12作为肝癌的基因治疗进一步提供理论依据和探索,期待在将来应用IL-12为基础的基因治疗一定会为包括肝癌在内的肿瘤治疗提供新的途径。     

溶瘤腺病毒治疗肿瘤的研究进展

溶瘤腺病毒是一种改造过的能够选择性地在肿瘤细胞中复制,并能够杀死肿瘤细胞的腺病毒,目前已经应用于肿瘤治疗中。但是因为肿瘤的复杂性以及高突变性,所以提高溶瘤腺病毒对肿瘤的有效性,选择性和安全性成为了主要的研究方向。能够在体内正常表达shRNA、细胞因子、自杀基因、基质修饰蛋白等治疗性基因的溶瘤腺病毒具有比单纯的溶瘤腺病毒更强的抗肿瘤活性。而具有肿瘤特异性启动子,尤其是双调控启动子的溶瘤腺病毒对肿瘤细胞具有更强的选择性杀伤作用。另外用脂质体、PEG聚合物、纳米颗粒、多肽等包裹的溶瘤腺病毒能够减少病毒的免疫原性以及对肝脏的毒性,增强了全身给药途径的抗肿瘤活性。特别是用PEG连上抗体、小肽、细胞因子和配体,能显著提高溶瘤腺病毒的选择性。因此,整合病毒载体与非病毒载体的优点并与免疫治疗相结合,是一个很有希望的提高病毒靶向治疗效果的策略。     

腺病毒载体的高分子修饰

腺病毒载体是基因治疗的常用载体之一,已经广泛应用于肿瘤和遗传疾病等的基因治疗研究中.但是临床发现腺病毒载体有较高的免疫原性,同时缺乏组织或细胞特异性,制约了其在临床上的应用.通过共价键结合或者静电力作用,将高分子修饰到病毒衣壳上,利用高分子的特殊性质可以降低载体的免疫原性和提高载体的靶向性,同时载体保持了较高的转染能力...     

辅助病毒依赖型腺病毒载体研究进展

摘要：辅助病毒依赖型腺病毒载体（helper-dependent adenoviral vector,HDAd）缺乏所有腺病毒的编码序列,与非复制型的第一代腺病毒载体（first-generation adenovirus vector,FGAd）相比,具有载体免疫原性低、安全、转移容量大和持续表达等特点,现广泛用于遗传性疾病、神经退行性疾病和肿瘤等的基因治疗和特异性靶向治疗研究。本文综述了HDAd构建和应用等方面的研究进展及未来的发展方向。     

与CIK细胞结合的肿瘤特异性增殖腺病毒KGHV400的构建

为了构建能与CIK细胞(Cytokine induced killer cell,CIK)结合的肿瘤特异性增殖腺病毒,我们用化学合成的35型腺病毒(Ad35)纤毛基因替换5型腺病毒(Ad5)骨架质粒的纤毛基因,获得5/35嵌合型腺病毒骨架质粒,然后与携带肿瘤特异性启动子hTERT(端粒酶逆转录酶基因启动子)和HRE(缺氧反应元件启动子)的穿梭质粒在HEK293细胞中同源重组,获得能与CIK细胞结合的肿瘤特异性增殖腺病毒KGHV400。分离人外周血单个核细胞,诱导培养成CIK细胞,与KGHV400共培养获得荷载KGHV400的CIK细胞。建立乳腺癌裸鼠移植瘤模型,经尾静脉注射荷载KGHV400的CIK细胞,在注射后第1d、2d、3d、5d、7d、14d解剖实验鼠,用免疫组化技术检测腺病毒六邻体蛋白在移植瘤、心、肝、脾、肾组织的表达。结果显示,构建的重组腺病毒KGHV400能高效率感染CIK细胞;荷瘤鼠尾静脉注射荷载KGHV400的CIK细胞后第1d,肿瘤细胞中即有腺病毒六邻体蛋白表达,之后表达逐渐增多,第14d仍有表达;脾脏在第1~14d检测到少量淋巴细胞中存在腺病毒六邻体蛋白;心、肝、肾组织未检测到该蛋白。对照组(尾静脉注射KGHV400)在注射后第1d、2d、3d、5d,肝、脾、肾组织中检测到存在腺病毒六邻体蛋白,但第7d后为转阴性;肿瘤细胞和心肌细胞未检测到腺病毒六邻体蛋白。我们的研究结果表明,重组腺病毒KGHV400是一种有用的肿瘤基因治疗载体。     

选择性复制型腺病毒介导的自杀基因HSV -tk 在 肿瘤基因治疗中的应用

自杀基因治疗是肿瘤基因治疗的手段之一,治疗效果与自杀基因能否被高效、选择性的导入肿瘤细胞有关。肿瘤选择性复制型腺病毒（conditionally replication adenovirus,CRADs）可以特异性的在肿瘤细胞中复制,在复制的同时所携带的治疗基因也大量表达。由CRAds介导的自杀基因,实现了对肿瘤的病毒治疗和基因治疗的结合,提高了治疗效率和使用复制型腺病毒的安全性。     

荷载金黄色葡萄球菌肠毒素A 基因的双调控溶瘤腺病毒载体 的构建、鉴定及其抗膀胱肿瘤作用

目的:构建表达超抗原金黄色葡萄球菌肠毒素A基因的双调控选择增殖型溶瘤腺病毒SG502-SEA及对照组携带超抗原SEA基因的非增殖溶瘤腺病毒DC318-SEA,并探讨其潜在的抗膀胱肿瘤作用.方法:将超抗原SEA基因片段经SpeⅠ和SalⅠ双酶切后,克隆入非增殖溶瘤腺病毒载体pSG218中,将鉴定正确的腺病毒载体命名为pDC318-SEA.同样方法将超抗原SEA基因片段克隆入双调控特异性增殖溶瘤腺病毒载体pSG502中,将鉴定正确的腺病毒载体命名为pSG502-SEA.将以上两种携带SEA基因的病毒载体与病毒骨架质粒PPE3-ccdB共转染293细胞,9～14d出现病毒空斑,经过3次病毒空斑纯化,提取腺病毒DNA,应用PCR进行鉴定,经鉴定正确的腺病毒分别命名为DC318 - SEA和SG502-SEA.大量扩增后,氯化铯梯度离心纯化腺病毒,测病毒滴度.结果:经PCR及酶切鉴定,SEA基因成功克隆到两病毒载体中,可以表达SEA基因,且病毒滴度为2.5×101pfu/ml.结论:成功构建表达超抗原SEA基因的双调控增殖型溶瘤腺病毒SG502-SEA及对照组携带超抗原SEA基因的非增殖溶瘤腺病毒DC318-SEA,为下一步抗膀胱肿瘤体内外实验奠定基础.     

腺病毒介导的Her2基因RNAi载体的构建和鉴定

目的:构建腺病毒介导的Her2基因RNAi栽体.方法:构建含有Her2基因片断的siRNA质粒Her2-pSuppressor,通过特异性酶切将目的基因与穿梭载体pshuttle相连,再通过特异性酶切位点将目的片断与腺病毒DNA相连,并用PCR和酶切鉴定方法进行筛选和鉴定,获得重组腺病毒DNA.以Pac Ⅰ酶切线性化后转染包装含有腺病毒E1的HEK293细胞.以软琼脂平板上的空斑数量计算重组腺病毒的的滴度.结果:Xba Ⅰ Mlu Ⅰ双酶切鉴定Her2a-RNAi/pShuttle和Her2b.RNAi/pShuttle阳性重组子获得304bp的目的片段,重组腺病毒载体Adeno-Her2a-RNAi和Adeno-Her2b-RNAi经PCR扩增出同样大小片断,经线性化后用脂质体法转染293细胞,观察到细胞病变效应.病毒滴度达1.2× 108PFU/mL.结论:成功构建了Adeno-Her2-RNAi,为肿瘤的基因治疗奠定了良好的基础.     

Adenovirus-mediated suicide gene therapy using the human telomerase catalytic subunit (hTERT) gene promoter induced apoptosis of ovarian cancer cell line

Telomerase is a ribonucleoprotein complex the function of which is to add telomeric repeats (TTAGGG)(n) to chromosomal ends, and it is known to play an important role in cellular immortalization. Telomerase is highly active in most tumor cells, yet not in normal cells. As such, it may have possible applications in cancer gene therapy. Telomerase consists of two essential components, telomerase RNA template (hTR) and catalytic subunit (hTERT). hTERT is expressed only in cells and tissues positive for telomerase activity, i.e., tumor and fetal cells. We here tested the possibility of the utilization of the hTERT promoter in targeted cancer gene therapy. We cloned the hTERT promoter in the replace of the CMV promoter and sub-cloned HSV-TK gene to be controlled by hTERT gene promoter in adenovirus shuttle plasmid. Then we constructed recombinant adenovirus Ad-hT-TK, and infected them into normal and human gynecological cancer cell lines. Through these experiments, we identified the selective tumor specific cell death by Ad-hT-TK. Furthermore, FACS analysis and TUNEL assay suggests that the reduced viability is mediated through the induction of apoptosis, indicating that this approach may be a useful method for suppressing cancer growth in targeted cancer gene therapy. These results show that Ad-hT-TK could be used for gynecological cancer gene therapy.     

Activity of the Human Telomerase Catalytic Subunit (hTERT) Gene Promoter Could Be Increased by the SV40 Enhancer

Telomerase is a ribonucleoprotein complex of which the function is to add telomeric repeats to chromosomal ends. Telomerase consists of two essential components, the telomerase RNA template (hTR) and the catalytic subunit (hTERT). hTERT is expressed only in cells and tissues positive for telomerase activity, i.e., tumor and fetal cells. The aim of this study is to test the increased telomerase promoter activity for cancer gene therapy in adenovirus vector. We cloned the hTERT promoter in place of the SV40 promoter in the pGL3-contol vector to be increased by the SV40 enhancer sequences, resulting in strong expression of luc+ only in telomerase positive cancer cells. Then we transfected the constructed plasmid into a normal human cell line and several cancer cell lines. Through these experiments, we identified the selective and increased expression of the luciferase gene controlled by the hTERT promoter and the SV40 enhancer in the telomerase positive cancer cell lines. To investigate the possibility of utilizing the hTERT promoter and the SV40 enhancer in targeted cancer gene therapy, we constructed an adenovirus vector expressing HSV-TK controlled by the hTERT promoter and the SV40 enhancer for the induction of specific telomerase positive cancer cell death. NSCLC cells infected by Ad-hT-TK-enh were more significantly suppressed and induced apoptosis than those infected by Ad-hT-TK. Telomerase is activated in 80～90% of cancers, so adenovirus with increasing telomerase promoter activity might be used for targeted cancer gene therapy using suicide genes. These results show that the hTERT promoter and the SV40 enhancer might be used for targeted cancer gene therapy.     

Activity of the human telomerase catalytic subunit (hTERT) gene promoter could be increased by the SV40 enhancer

Telomerase is a ribonucleoprotein complex of which the function is to add telomeric repeats to chromosomal ends. Telomerase consists of two essential components, the telomerase RNA template (hTR) and the catalytic subunit (hTERT). hTERT is expressed only in cells and tissues positive for telomerase activity, i.e., tumor and fetal cells. The aim of this study is to test the increased telomerase promoter activity for cancer gene therapy in adenovirus vector. We cloned the hTERT promoter in place of the SV40 promoter in the pGL3-contol vector to be increased by the SV40 enhancer sequences, resulting in strong expression of luc+ only in telomerase positive cancer cells. Then we transfected the constructed plasmid into a normal human cell line and several cancer cell lines. Through these experiments, we identified the selective and increased expression of the luciferase gene controlled by the hTERT promoter and the SV40 enhancer in the telomerase positive cancer cell lines. To investigate the possibility of utilizing the hTERT promoter and the SV40 enhancer in targeted cancer gene therapy, we constructed an adenovirus vector expressing HSV-TK controlled by the hTERT promoter and the SV40 enhancer for the induction of specific telomerase positive cancer cell death. NSCLC cells infected by Ad-hT-TK-enh were more significantly suppressed and induced apoptosis than those infected by Ad-hT-TK. Telomerase is activated in 80 approximately 90% of cancers, so adenovirus with increasing telomerase promoter activity might be used for targeted cancer gene therapy using suicide genes. These results show that the hTERT promoter and the SV40 enhancer might be used for targeted cancer gene therapy.     

Aptamer modification improves the adenoviral transduction of malignant glioma cells

Adenovirus has shown increasing promise in the gene-viral therapy for glioblastoma, a treatment strategy that relies on the delivery of viruses or transgenes into tumor cells. However, targeting of adenovirus to human glioblastoma remains a challenge due to the low expression level of coxsackie and adenovirus receptor (CAR) in glioma cells. Aptamers are small and highly structured single-stranded oligonucleotides that bind at high affinity to a target molecule, and are good candidates for targeted imaging and therapy. In this study, to construct an aptamer-modified Ad5, we first genetically modified the HVR5 of Ad hexon by biotin acceptor peptide (BAP), which would be metabolically biotinylated during production in HEK293 cells, and then attached the biotin labeled aptamer to the modified Ad through avidin–biotin binding. The aptamers used in this study includes AS1411 and GBI-10. The former is a DNA aptamer that can bind to nucleolin, a nuclear matrix protein found on the surface of cancer cells. The latter is a DNA aptamer that can recognize the extracellular matrix protein tenascin-C on the surface of human glioblastoma cells. To examine if aptamer-modification of the hexon protein could improve the adenoviral transduction efficiency, a glioblastoma cell line, U251, was transduced with aptamer-modified Ads. The transduction efficiency of AS1411- or GBI-10-modified Ad was approximately 4.1-fold or 5.2-fold higher than that of the control. The data indicated that aptamer modified adenovirus would be a useful tool for cancer gene therapy.     

Enhanced expression of apoptin by the Myc-Max binding motif and SV40 enhancer for SCLC gene therapy

Apoptin is derived from chicken anemia virus (CAV) and known to induce tumor specific apoptosis but not normal cells. The aim of this study was to use increased expression of apoptin by the Myc-Max response element (MMRE) and SV40 enhancer in small-cell lung cancer (SCLC) gene therapy. To investigate the possibility of the utilization of the MMRE, apoptin, and SV40 promoter/enhancer in targeted cancer gene therapy, adenovirus vector expressing apoptin controlled by the MMRE, and SV40 promoter/enhancer was constructed. Ad-MMRE-apoptin-enh infected SCLC cells were significantly suppressed and induced apoptosis more than those of Ad-apoptin or Ad-apoptin-enh. Infection with Ad-MMRE-apoptin-enh of normal cells did not increase apoptosis. About 85% of SCLC tumors show overexpression of the myc family, so the increased expression of apoptin by MMRE and SV40 enhancer can be used in targeted SCLC gene therapy. These results indicate that apoptin expression was increased by the MMRE and SV40 promoter/enhancer, and that this strategy can be used in SCLC targeted cancer gene therapy.     

Targeting lung cancer stem‐like cells with TRAIL gene armed oncolytic adenovirus

Lung cancer stem cell (LCSC) is critical in cancer initiation, progression, drug resistance and relapse. Disadvantages showed in conventional lung cancer therapy probably because of its existence. In this study, lung cancer cell line A549 cells propagated as spheroid bodies (named as A549 sphere cells) in growth factors‐defined serum‐free medium. A549 sphere cells displayed CSC properties, including chemo‐resistance, increased proportion of G0/G1 cells, slower proliferation rate, ability of differentiation and enhanced tumour formation ability in vivo. Oncolytic adenovirus ZD55 carrying EGFP gene, ZD55‐EGFP, infected A549 sphere cells and inhibited cell growth. Tumour necrosis factor‐related apoptosis‐inducing ligand (TRAIL) armed oncolytic adenovirus, ZD55‐TRAIL, exhibited enhanced cytotoxicity and induced A549 sphere cells apoptosis through mitochondrial pathway. Moreover, small molecules embelin, LY294002 and resveratrol improved the cytotoxicity of ZD55‐TRAIL. In the A549 sphere cells xenograft models, ZD55‐TRAIL significantly inhibited tumour growth and improved survival status of mice. These results suggested that gene armed oncolytic adenovirus is a potential approach for lung cancer therapy through targeting LCSCs.     

Adenovirus-mediated suicide SCLC gene therapy using the increased activity of the hTERT promoter by the MMRE and SV40 enhancer

Telomerase is a ribonucleoprotein complex of which the function is to add telomeric repeats to chromosomal ends. Telomerase consists of two essential components, the telomerase RNA template (hTR) and the catalytic subunit (hTERT). hTERT is expressed only in cells and tissues positive for telomerase activity, i.e., tumor or stem cells. The aim of this study was to use increased telomerase promoter activity in small-cell lung cancer (SCLC) gene therapy. The hTERT promoter and Myc-Max response elements (MMRE) in pGL3-Control vector containing SV40 enhancer resulted in strong expression of the luciferase gene only in telomerase positive and myc overexpressing SCLC cell line but not in normal human cell line. To investigate the possibility of the utilization of the MMRE, hTERT promoter, and SV40 enhancer in targeted SCLC gene therapy, adenovirus vector expressing HSV-TK controlled by the MMRE, hTERT promoter, and SV40 enhancer for the induction of telomerase positive and myc-overexpressing cancer specific cell death was constructed. SCLC cells infected with Ad-MMRE-hT-TK-enh were significantly suppressed and induced apoptosis more than those of Ad-hT-TK or Ad-hT-TK-enh infected cells. Telomerase and c-myc are activated in 60 approximately 80% of SCLC, so the increased activity of telomerase promoter can be used for targeted SCLC gene therapy. These results show that the MMRE, hTERT promoter, and SV40 enhancer can be used in SCLC targeted cancer gene therapy.     

聚合物纳米粒在肿瘤光动力治疗中的研究进展

光动力治疗创伤小,在恶性肿瘤治疗方面的应用已经得到了临床认可。治疗过程中需要给予光敏剂,在光照下产生分子氧对肿瘤细胞产生杀伤作用。但是,大多数光敏剂缺乏对肿瘤细胞的特异性,其在肿瘤中的富集主要与细胞高代谢有关,并且在水相媒介中溶解度比较差。纳米技术应用于光动力治疗提供了一种有效地体内运输光敏剂的方式。目前,聚合物纳米粒与光动力药物传递的研究越来越多,光敏剂通过纳米粒的运输为弥补光动力治疗的不足提供了可能,这是因为纳米载体可以将治疗浓度的光敏剂运送到肿瘤细胞而不造成非靶向组织的副损伤。本文将介绍对肿瘤光动力治疗中具有特异性的聚合物纳米粒的种类及在临床中的应用情况,为肿瘤靶向治疗提供新思路。