Cancer targeting gene-viro-therapy specific for liver cancer by α-fetoprotein-controlled oncolytic adenovirus expression of SOCS3 and IL-24

The combination of gene therapy and virotherapy for cancer treatment has received close attention and has become a trend in the field of cancer biotherapy. A strategy called 'Cancer Targeting Gene-Viro-Therapy' (CTGVT) or 'Gene Armed Oncolytic Viral Therapy' (GAOVT) has been proposed, in which an antitumor gene is inserted into an oncolytic viral vector. In our previous study, a dual-regulated oncolytic adenovirus with enhanced safety for normal cells and strict liver cancer-targeting ability, designated Ad?enAFP?E1A?E1B (Δ55) (briefly Ad?enAFP?D55), was successfully constructed. In the current work, interleukin-24 (IL-24) and suppressor of cytokine signaling 3 (SOCS3) genes were packaged into Ad?enAFP?D55. The new constructs, Ad?enAFP?D55-(IL-24) and Ad?enAFP?D55-(SOCS3), showed improved tumoricidal activity in hepatoma cell lines compared with the oncolytic viral vector Ad?enAFP?D55. The co-administration of Ad?enAFP?D55-(IL-24) and Ad?enAFP?D55-(SOCS3) showed much better antitumor effect than Ad?enAFP?D55-(IL-24) or Ad?enAFP?D55-(SOCS3) alone both in vitro and in a nude mouse xenograft model. Moreover, our results also showed that blockade of the Jak/Stat3 pathway by Ad?enAFP?D55-(SOCS3) infection in HuH-7 cells could down-regulate some anti-apoptosis proteins, such as XIAP, Bcl-xL, and survivin, which might sensitize the cells to Ad?enAFP?D55-(IL-24)-induced apoptosis. These results indicate that co-administration of Ad?enAFP?D55-(IL-24) and Ad?enAFP?D55-(SOCS3) may serve as a candidate therapeutic approach for the treatment of liver cancer.     

Dichloroacetate (DCA) enhances tumor cell death in combination with oncolytic adenovirus armed with MDA-7/IL-24

Dichloroacetate (DCA) is a metabolic modulator for the treatment of lactic acidosis and inherited mitochondrial diseases. A recent study showed that DCA treatment could induce apoptosis in many kinds of tumor cell lines via mitochondrial apoptotic pathway while sparing normal cells. ONYX-015 (dl 1520) is one of the oncolytic adenoviruses developed by the deletion of E1B-55kD gene of type 5 adenoviral DNA, and it replicates efficiently and selectively in tumor cells. ZD55-IL-24, an E1B-55kD deleted oncolytic adenovirus carrying interleukin-24 (IL-24, also called melanoma differentiation associated gene-7), had showed potent antitumor efficacy in a variety of tumor cells and exerted no apparent toxicity on normal cells. Given both the good therapeutic effect and low toxicity of these agents, here we investigated whether DCA in combination with ZD55-IL-24 or ONYX-015 could have more efficient antitumor activity in vitro experiments. Therefore, we tested the cytotoxicity of combination therapy in normal hepatic cells L-02 and QSG-7701 using the MTT assay. Our results showed that DCA combined with ONYX-015 or ZD55-IL-24 exhibited more potent antitumor activity than DCA or virus alone, and the combination treatment did not have superimposed toxicities in normal cells. Thus, a novel combination therapy associating oncolytic adenoviruses with relatively low toxic drug without severe side effects was proposed.     

Synergistic antitumor effect of TRAIL and IL-24 with complete eradication of hepatoma in the CTGVT-DG strategy

The ZD55-tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) and ZD55-interleukin (IL)-24 were constructed by inserting TRAIL or IL-24 gene separately into the oncolytic adenovirus named ZD55 (with adenovirus E1B-55kD deletion). The resulting ZD55-TRAIL and ZD55-IL-24 were used in combination to treat xenograft tumors in nude mice model. The results showed that it can not only completely eliminate BEL7404 hepatoma xenograft but also have excellent antitumor effect against gaster, lung, prostate, and breast carcinomas. It was also found that ZD55-TRAIL could not only suppress the tumor growth promoting effect by ZD55-IL-24 at lower dosage, but also substantially reduce the cancer cell viability in their combined use. This is because ZD55-IL-24 and ZD55-TRAIL could mutually enhance each other's antitumor effect greatly. All these findings conspicuously showed the synergistic antitumor effect of TRAIL and IL-24, which is also the reason for the antitumor effect by the combined use of TRAIL and IL-24 in vitro and also in vivo.     

Targeting gene-virotherapy for cancer

Gene therapy and viral therapy for cancer have therapeutic effects, but there has been no significant breakthrough in these two forms of therapy. Therefore, a new strategy called “targeting gene-virotherapy”, which combines the advantages of gene therapy and viral therapy, has been formulated. This new therapy has stronger antitumor effects than either gene therapy or viral therapy. A tumor-specific replicative adenovirus vector ZD55 （E1B55KD deleted Adv.） was constructed and various single therapeutic genes were inserted into ZD55 to form ZD55-gene. These are the targeting gene-virotherapy genes. But experiments showed that a single gene was not effective in eliminating the tumor mass, and therefore two genes were separately inserted into ZD55. This strategy is called “targeting dual gene-virotherapy” （with PCT patent）. Better results were obtained with this strategy, and all the xenograft tumor masses were completely eliminated in all mice when two suitable genes producing a synergetic or compensative effect were chosen. Twenty-six papers on these strategies have been published by researchers in our laboratory. Furthermore, an adenoviral vector with two targeting promoters harboring two antitumor genes has been constructed for cancer therapy. Promising results have been obtained with this adenoviral vector and another patent has been applied for. This antitumor strategy can be used to kill tumor cells completely with minimum damage to normal cells.     

Targeting gene-virotherapy of cancer

Our purpose is to completely elimination of xenograft tumor in animal tumor model in order to work out a protocal for the cure of patient. Gene therapy and viral therapy for cancer have got some therapeutic effects, but both have no great breakthrough. Therefore, we worked out a new strategy called Targeting Gene-Virotherapy of Cancer which is a combination of the advantage of gene therapy and virotherapy. This new strategy has stronger antitumor effect than either of them alone. A tumor specific replicative adenovirus vector ZD55 (E1B 55KD deleted Adv.) which is similar to ONYX-015 in targeting fuction but significant different in construction was produced and various single therapeutic gene was inserted into ZD55. Now such a conception as Targeting Gene-Virotherapy of Cancer was raised and systemically studied before, although there are some works on ONYX-015-tk, -cd or cd/-tk etc. separately. The antitumor effect of ZD55-Gene (for example IL-24 gene) is much better than ZD55 (virotherapy) alone and hundred fold high than that of Ad-IL-24 (gene therapy) alone. ZD55-IL-24 was in preclinal studying in the ZD55-IL-24 therapy, completely elimination of tumor mass was occurred in some mice but not in all mice, that means one gene was not effictive enough to eliminate all the tumor mass in all mice. Therefore two genes with compensative or synergetic effect were inserted into ZD55 separately and used in combination. This strategy was called Targeting Dual Gene-Virotherapy of Cancer (with PCT patent). Then much better results were obtained and all the xenograft tumor masses were completely eliminated in all mice, if two suitable genes were chosen. On the basis of the initiation of two gene results, it was thought about that using two tumors promoter to control the virus vector will be better for the targeting effect and the safty of the drugs. Then double tumor controlled virus vector harboring two genes for cancer therapy was worked out. Better results have been obtained and another patent has been applied. This antitumor strategy could be used to kill all the tumor cells completely in all mice with minimum damage to normal cells.     

Synergistic induction of tumor cell death by combining cisplatin with an oncolytic adenovirus carrying TRAIL

Chemoresistance and side effects are considered as the major obstacles in cisplatin-based chemotherapy of various human malignant tumors. Conjugation with cancer-specific apoptotic stimuli TRAIL or typical viro-agent ONYX-015 has been extensively investigated to enhance the antitumor activity of cisplatin. In this study, we presented a novel chemo-gene-virotherapeutic strategy to further improve the toxic effects in cancer cells and reduce the damage in normal cells. Here, an oncolytic adenoviral vector (ZD55), with a deletion of E1B 55-kDa gene, was employed to express the therapeutic TRAIL gene by constructing a recombinant virus ZD55-TRAIL. Exogenous gene delivery efficacy was determined by both in vitro and in vivo experiments and enhanced cytotoxicity of combined treatment of ZD55-TRAIL with cisplatin was evaluated in several cancer cell lines. Moreover, negative effects on normal cells have been tested in both L-02 and MRC-5 cell lines by MTT assay and apoptotic cell staining. According to our observation, combination of ZD55-TRAIL with cisplatin exhibited an apparent synergistic cytotoxicity in cancer cells, yet significantly abolished the negative toxicity in normal cells by reducing the dosage. Thus, a novel chemo-gene-virotherapeutic strategy for cancer therapy was proposed.     

Cancer targeting gene-viro-therapy for pancreatic cancer using oncolytic adenovirus ZD55-IL-24 in immune-competent mice

Cancer targeting gene-viro-therapy (CTGVT) may prove to be an effective treatment for pancreatic cancer (PC). This study was intended to explore the anti-tumor effect of ZD55-IL-24 (oncolytic adenovirus ZD55 harboring IL-24) on PC in immune-competent mice. The expression of gene harbored by oncolytic adenovirus ZD55 in PC cells was detected by reporter-gene assays. The in vitro anti PC ability of ZD55-IL-24 was tested by MTT, crystal violet staining and apoptosis assays. The in vivo anti PC effect of ZD55-IL-24 was further observed in an immune-competent mice model by detecting anti-tumor immunity and induction of apoptosis. The expression of gene harbored by ZD55 in PC cells was significantly higher than that harbored by the replicated-deficient adenovirus, and the amount of gene expression was time-dependent and dose-dependent. Both ZD55-IL-24 and ZD55 inhibited PC cells growth, but the anti-tumor effect of ZD55-IL-24 was significantly stronger than that of ZD55, and the ability of ZD55-IL-24 in inducing PC apoptosis was significantly stronger than that of ZD55. The tumor-forming rate of group ZD55-IL-24 was the lowest, and the tumor-growing rate was also significantly lower than that of group ZD55 in immune-competent PC models. Moreover, ZD55-IL-24 mediated more anti-cancer immunity effects by induction of stronger T-lymphocytes response to PC cells, higher levels of γ-IFN and IL-6 cytokines. ZD55-IL-24-mediated CTGVT could inhibit PC growth not only by inducing oncolysis and apoptosis but enhancing the anti-cancer immune effects by inducing T cell response to PC and up-regulating γ-IFN and IL-6 cytokine in immune-competent mice. This may serve as a candidate therapeutic approach for the treatment of PC.     

雷帕霉素联合ZD55-TRAIL病毒对肿瘤抑制及其机制探讨

溶瘤腺病毒的肿瘤靶向性研究一直是一个热点。目前已有商业化的ONYX-015、H101溶瘤腺病毒。在此基础上,科学家又进一步发展形成基因-病毒治疗方案,如文中应用的ZD55-TRAIL病毒。本研究利用刘新垣实验室提供的携带TRAIL(TNF-related apoptosis-inducing ligand,TNF相关的凋亡诱导配体)的溶瘤腺病毒ZD55-TRAIL联合雷帕霉素杀伤肿瘤     

A double-regulated oncolytic adenovirus with improved safety for adenocarcinoma therapy

Safety and efficiency are equally important to be considered in developing oncolytic adenovirus. Previously, we have reported that ZD55, an oncolytic adenovirus with the deletion of E1B-55K gene, exhibited potent antitumor activity. In this study, to improve the safety of ZD55, we utilized MUC1 promoter to replace the native promoter of E1A on the basis of ZD55, and generated a double-regulated adenovirus, named MUD55. Our data demonstrated that the expression of early and late genes of MUD55 was both reduced in MUC1-negative cells, resulting in its stricter glandular-tumor selective progeny production. The cytopathic effect of MUD55 was about 10-fold lower than mono-regulated adenovirus ZD55 or Ad.MUC1 in normal cells and not obviously attenuated in glandular tumor cells. Moreover, MUD55 showed the least liver toxicity when administrated by intravenous injection in nude mice. These results indicate that MUD55 could be a promising candidate for the treatment of adenocarcinoma.     

癌症靶向基因-病毒ZD55-XAF1抗肝癌移植瘤的生长及其安全性研究

目的:探讨溶瘤腺病毒(ZD55-gene)作为载体携带外源抗癌基因(XAF1)抗肝癌移植瘤的生长及其安全性。方法:抽提溶瘤腺病毒ZD55-XAF1的基因组DNA,PCR扩增鉴定病毒;细菌平板培养和支原体检测试剂盒检测细胞有无细菌、支原体污染;通过荷瘤小鼠动物实验,观察溶瘤腺病毒ZD55-XAF1对肝癌移植瘤生长的抑制、小鼠的临床反应指标、血清肝毒性指标、各脏器组织中的病毒残留分布及病理切片观察。结果:细胞培养过程无细菌和支原体污染;较对照组,受试小鼠血清肝酶AST活性上升(P0.05),而ALT和ALP活性基本无变化(P0.05);PCR检测各脏器均有病毒基因组DNA存在;HE染色显示受试小鼠各脏器具有不同程度的损伤,病毒处理对肿瘤细胞具有明显的杀伤效果,而受试小鼠的临床反应并无明显异常。结论:溶瘤腺病毒ZD55-XAF1能够抑制肿瘤生长,杀死肿瘤细胞,对小鼠血清肝酶活性影响较小而对各脏器有不同程度的轻微损伤,作为癌症基因治疗载体有潜在的应用价值但其安全性还有待提高。     

survivin启动子驱动的shRNA在宫颈癌SiHa细胞中的特异性表达

研究survivin启动子驱动的小发夹RNA(shRNA)在宫颈癌SiHa细胞中的特异性表达.PCR扩增survivin启动子,构建以survivin启动子驱动增强绿色荧光蛋白(EGFP)表达的真核表达载体pEGFP-C1/Surv,并检测survivin启动子的活性;构建针对EGFP的shRNA真核表达载体pGenesil-1-EGFP-shRNA/U6,并检测shRNA在U6启动子驱动下的干扰效果;用有活性的survivin启动子取代pGenesil-1-EGFP-shRNA/U6载体中的U6启动子,从而获得新的shRNA真核表达载体pGenesil-1-EGFP-shRNA/Surv;将pGenesil-1-EGFP-shRNA/Surv转染到宫颈癌SiHa细胞及正常人脐静脉内皮HuVEC细胞,观察EGFP在两种细胞中的表达变化.结果表明,成功扩增survivin启动子并验证该启动子具有活性;成功构建EGFP shRNA真核表达载体pGenesil-1-EGFP-shRNA/U6,并验证shRNA在U6启动子驱动下具有较好的干扰效果;成功构建pGenesil-1-EGFP-shRNA/Surv载体,分别转染SiHa及HuVEC细胞,在SiHa 细胞中观察到较少的绿色荧光蛋白表达,而在HuVEC细胞中观察到较多的绿色荧光蛋白表达.survivin启动子能驱动shRNA在宫颈癌SiHa细胞中特异性表达,而在正常HuVEC细胞中不表达.     

Ad-IL-24对SGC-7901胃癌细胞生长抑制的体外实验

旨在研究携带人IL-24基因的腺病毒表达载体(Ad-IL-24)对SGC-7901人胃癌细胞的生长抑制作用并分析其分子机制。以不同MOI(感染复数)的Ad空载体腺病毒感染SGC-7901人胃癌细胞,筛选出最佳感染剂量;Ad-IL-24以最佳感染剂量感染SGC-7901胃癌细胞,RT-PCR法和Western blotting法检测腺病毒介导的IL-24基因在SGC-7901胃癌细胞中的转录;MTT法检测Ad-IL-24对SGC-7901胃癌细胞的生长抑制作用,流式细胞仪检测其诱导SGC-7901人胃癌细胞凋亡和细胞周期改变的效应,Hoechst33258染色荧光显微镜检测其诱导胃癌细胞凋亡的核形态改变;RT-PCR半定量法进一步检测SGC-7901胃癌细胞中凋亡相关基因的转录。结果显示,100MOI为感染SGC-7901胃癌细胞的腺病毒最佳感染剂量;Ad-IL-24能成功介导IL-24基因在SGC-7901胃癌细胞中转录性表达;Ad-IL-24感染SGC-7901胃癌细胞后,能明显抑制胃癌细胞生长和诱导凋亡;Ad-IL-24能显著上调SGC-7901胃癌细胞中bax、caspase-3和p53的表达和下调bc...     

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.     

A bidirectional Tet-dependent promotor construct regulating the expression of E1A for tight control of oncolytic adenovirus replication

Tight regulation of oncolytic adenoviruses (oAdV) represents an important requirement for their safe application. Here we describe a new doxycycline (Dox)-dependent oAdV with a bidirectional expression cassette, which drives the expression of the reverse tetracycline-controlled transactivator (rtTA(s)-M2) from a lung tumor-specific promoter and, in the opposite direction, the expression of the adenoviral E1A gene from a second generation TetO(7) sequence linked to an isolated TATA box. In H441 lung cancer cells, this oAdV showed a strictly Dox-dependent E1A expression, adenoviral replication, cell killing activity and a 450-fold induction of progeny virus production. The virus could be shut off again by withdrawal of Dox and, in contrast to a control oAdV expressing E1A directly from the SP-B promoter, did not replicate in non-target cells. However, the absolute values of virus production and the cell killing activity in the presence of the inducer were still reduced as compared to the control oAdV. The results demonstrate, for the first time, Dox-dependent oAdV replication from a single adenoviral vector genome. Future improvement of the Dox-dependent E1A regulation cassette should lead to the generation of an oAdV well suited to meet the demands for a highly regulated and efficient oncolytic virus for in vivo applications.     

Tissue-specific, tumor-selective, replication-competent adenovirus vector for cancer gene therapy

We have previously described two replication-competent adenovirus vectors, named KD1 and KD3, for potential use in cancer gene therapy. KD1 and KD3 have two small deletions in the E1A gene that restrict efficient replication of these vectors to human cancer cell lines. These vectors also have increased capacity to lyse cells and spread from cell to cell because they overexpress the adenovirus death protein, an adenovirus protein required for efficient cell lysis and release of adenovirus from the cell. We now describe a new vector, named KD1-SPB, which is the KD1 vector with the E4 promoter replaced by the promoter for surfactant protein B (SPB). SPB promoter activity is restricted in the adult to type II alveolar epithelial cells and bronchial epithelial cells. Because KD1-SPB has the E1A mutations, it should replicate within and destroy only alveolar and bronchial cancer cells. We show that KD1-SPB replicates, lyses cells, and spreads from cell to cell as well as does KD1 in H441 cells, a human cancer cell line where the SPB promoter is active. KD1-SPB replicates, lyses cells, and spreads only poorly in Hep3B liver cancer cells. Replication was determined by expression of the E4ORF3 protein, viral DNA accumulation, fiber synthesis, and virus yield. Cell lysis and vector spread were measured by lactate dehydrogenase release and a "vector spread" assay. In addition to Hep3B cells, KD1-SPB also did not express E4ORF3 in HT29.14S (colon), HeLa (cervix), KB (nasopharynx), or LNCaP (prostate) cancer cell lines, in which the SPB promoter is not expected to be active. Following injection into H441 or Hep3B tumors growing in nude mice, KD1-SPB caused a three- to fourfold suppression of growth of H441 tumors, similar to that seen with KD1. KD1-SPB had only a minimal effect on the growth of Hep3B tumors, whereas KD1 again caused a three- to fourfold suppression. These results establish that the adenovirus E4 promoter can be replaced by a tissue-specific promoter in a replication-competent vector. The vector has three engineered safety features: the tissue-specific promoter, the mutations in E1A that preclude efficient replication in nondividing cells, and a deletion of the E3 genes which shield the virus from attack by the immune system. KD1-SPB may have use in treating human lung cancers in which the SPB promoter is active.     

Targeting gene-virotherapy of cancer and its prosperity

Gene and viral therapies for cancer have shown some therapeutic effects, but there has been a lack of real breakthrough. To achieve the goal of complete elimination of tumor xenograft in animal models, we have developed a new strategy called Targeting Gene-Virotherapy of Cancer, which aims to combine the advantages of both gene therapy and virotherapy. This new strategy has produced stronger anti-tumor effects than either gene or viral therapy alone. A tumorspecific replicative adenovirus vector, designated as ZD55, was constructed by deletion of the 55kDa E1B region of adenovirus. The resulting viral construct not only retains a similar function to ONYX-015 by specifically targeting p53 negative tumors, but also allows for the insertion of various therapeutic genes to form appropriate ZD55 derivatives due to the newly introduced cloning site, a task not feasible with the original ONYX-015 virus. We showed that the anti-tumor effect of one such derivative, ZD55-IL-24, is at least 100 times more potent than that of either ZD55 virotherapy or Ad-IL-24 gene therapy. Nevertheless, complete elimination of tumor mass by the use of ZD55-1L-24 was only observed in some but not all mice, indicating that one therapeutic gene was not sufficient to ＂cure＂ these mice. When genes with complementary or synergetic effects were separately cloned into the ZD55 vector and used in combination （designated as the Dual Gene Therapy strategy）, much better results were obtained; and it was possible to achieve complete elimination of all the xenograft tumor masses in all mice if two suitable genes were chosen. More comprehensive studies based on this new strategy will likely lead to a protocol for clinical trial. Finally, the concept of Double Controlled Targeting Virus-Dual Gene Therapy for cancer treatment, and the implication of the recent progress in cancer stem cells are also discussed.