Development of a transferrin receptor-targeting HVJ-E vector

The development of more effective cancer treatments is anticipated. Tumor-targeted drug delivery is an important strategy in cancer therapy. We have developed an HVJ (hemagglutinating virus of Japan; Sendai virus) envelope (HVJ-E) vector using inactivated Sendai virus. The HVJ-E vector has been observed to target a number of cell lines since its hemagglutinin-neuraminidase (HN) protein recognizes the sialic acids of host cells. Thus, to reduce non-specific binding of the HVJ-E vector, we eliminated HN protein using HN-specific short interfering RNA (siRNA). Then, to further increase its tumor-targeting ability, we constructed HN-depleted HVJ containing the F-transferrin chimeric protein. The modified vectors containing Q-dots demonstrated 32-fold greater tumor-targeting efficiency than wild-type HVJ-E.     

Anticancer immunotherapy using inactivated Sendai virus particles

Ultraviolet-inactivated, replication-defective Sendai virus particles (Hemagglutinating virus of Japan envelope, HVJ-E) injected into murine colon carcinoma (CT26) tumors growing in syngeneic Balb/c mice eradicated 60-80% of the tumors and obviously inhibited the growth of the remainder. Induced adaptive anti-tumor immune responses were dominant in the tumor eradication process because the effect was abrogated in severe combined immunodeficient (SCID) mice. Murine and human dendritic cells (DCs) underwent dose-dependent maturation by HVJ-E in vitro. Profiles of cytokines secreted by DCs after HVJ-E stimulation showed that the amount of IL-6 released was comparable to that elicited by live HVJ. Real-time RT-PCR and immunohistochemistry revealed that HVJ-E induced a remarkable infiltration of DCs, CD4+ and CD8+ T cells into tumors and CT26 specific cytotoxic T lymphocytes (CTL) were induced. On the other hand, conditioned medium from DCs stimulated by HVJ-E (H-DCCM) rescued CD4+CD25- effector T cell proliferation from Foxp3+CD4+CD25+ regulatory T cell (Treg) mediated suppression and IL-6 was presumably dominant for this phenomenon. We also confirmed such rescue in mice treated with HVJ-E in vivo. Moreover, anti-tumor effect of HVJ-E was significantly reduced by an in vivo blockade of IL-6 signaling. Depending on cancer cell types, it is also expected that HVJ-E eradicates tumor by its direct cytotoxity against cancer cells or activating NK cells. Because it can enhance anti-tumor immunity and simultaneously remove Treg mediated suppression, HVJ-E shows promise as a novel therapeutic for cancer immunotherapy.     

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.     

Rapid transport of plasmid DNA into the nucleolus via actin depolymerization using the HVJ envelope vector

BACKGROUND: Although nuclear transport of therapeutic genes is an essential requirement of human gene therapy, factors required for nuclear entry of DNA remain to be elucidated. Non-viral vector systems have led to numerous improvements in the efficiency of delivery of exogenous DNA into cells. However, nuclear transport of plasmid is difficult to achieve. METHODS: We examined nuclear translocation efficiency of Cy3-labeled plasmid DNA (Cy3-pDNA) delivered by the hemagglutinating virus of Japan envelope (HVJ-E) vector, Lipofectamine or microinjection. We also examined the effect of actin depolymerization on nuclear transport of Cy3-pDNA. RESULTS: Cy3-pDNA reached the nucleus, particularly in the nucleolus, in 30 min after fusion-mediated delivery using the HVJ-E vector, while the DNA was retained in the cytoplasm during the observed period after the delivery by cationic liposomes. HVJ-E treatment transiently depolymerized actin filaments, and acceleration of nucleolar entry of microinjected DNA was achieved when treated with either empty HVJ-E or cytochalasin D, an inhibitor of actin depolymerization, prior to microinjection. CONCLUSIONS: These results suggest that plasmid DNA can be transported rapidly from the cytoplasm to the nucleolus when actin filaments are depolymerized. Thus, the HVJ-E vector can accelerate the transport of DNA to the nucleolus by actin depolymerization.     

Biocompatible polymer enhances the in vitro and in vivo transfection efficiency of HVJ envelope vector

BACKGROUND: Vector development is critical for the advancement of human gene therapy. However, the use of viral vectors raises many safety concerns and most non-viral methods are less efficient for gene transfer. One of the breakthroughs in vector technology is the combination of the vector with various polymers. METHODS: HVJ (hemagglutinating virus of Japan) envelope vector (HVJ-E) has been developed as a versatile gene transfer vector. In this study, we combined HVJ-E with cationized gelatin to make it a more powerful tool and assessed its transfection efficiency in vitro and in vivo. In addition, we investigated the mechanism of the gene transfer by means of the inhibition of fusion or endocytosis. RESULTS: The combination of both protamine sulfate and cationized gelatin with HVJ-E, referred to as PS-CG-HVJ-E, further enhanced the in vitro transfection efficiency. In CT26 cells, the luciferase gene expression of PS-CG-HVJ-E was approximately 10 times higher than that of the combination of protamine sulfate with HVJ-E or the combination of cationized gelatin with HVJ-E, referred to as PS-HVJ-E or CG-HVJ-E, respectively. Furthermore, the luciferase gene expression in liver mediated by intravenous administration of CG-HVJ-E was much higher than the luciferase gene expression mediated by PS-HVJ-E or PS-CG-HVJ-E and approximately 100 times higher than that mediated by HVJ-E alone. CONCLUSIONS: Cationized gelatin-conjugated HVJ-E enhanced gene transfection efficiency both in vitro and in vivo. These results suggest that low molecular weight cationized gelatin may be appropriate for complex formation with various envelope viruses, such as retrovirus, herpes virus and HIV.     

Adeno-associated virus vectors for gene transfer to the brain

Gene therapy is a novel method under investigation for the treatment of neurological disorders. Considerable interest has focused on the possibility of using viral vectors to deliver genes to the central nervous system. Adeno-associated virus (AAV) is a potentially useful gene transfer vehicle for neurologic gene therapies. The advantages of AAV vector include the lack of any associated disease with a wild-type virus, the ability to transduce nondividing cells, the possible integration of the gene into the host genome, and the long-term expression of transgenes. The development of novel therapeutic strategies for neurological disorder by using AAV vector has an increasing impact on gene therapy research. This article describes methods that can be used to generate rodent and nonhuman primate models for testing treatment strategies linked to pathophysiological events in the ischemic brain and neurodegenerative disorders such as Parkinson's disease.     

肿瘤靶向治疗的新型细胞载体

肿瘤靶向性病毒作为一种特殊的肿瘤治疗药物和基因治疗载体近年来已得到长足发展,许多高效、靶向性病毒载体已被相继研究开发,但仍不能满足临床上肿瘤靶向治疗的需要,如何将这些靶向病毒准确而高效地运输到肿瘤病变部位仍然未得到充分解决.细胞因子诱导杀伤细胞(cytokine-inducedkillercells,CIK)作为肿瘤的细胞治疗方法之一已成功地在临床上得到了广泛应用.最近科学家使用CIK细胞作为病毒运载工具,成功地将病毒运载到肿瘤组织部位并显示出高效的抗肿瘤作用,该方法为病毒运输定位于肿瘤病变部位找到了突破口,实验资料显示其具有潜在的应用价值.     

基于痘苗病毒载体的恶性肿瘤基因治疗研究进展

基因治疗一直是肿瘤生物治疗的重要策略,而以溶瘤痘苗病毒为载体的肿瘤治疗近年来受到较多关注。该文总结了目前用于恶性肿瘤治疗的痘苗病毒和基于痘苗病毒载体的基因治疗研究进展及其在各个领域的成果。     

Gene therapy in cancer

Gene therapy, recently frequently investigated, is an alternative treatment method that introduces therapeutic genes into a cancer cell or tissue to cause cell death or slow down the growth of the cancer. This treatment has various strategies such as therapeutic gene activation or silencing of unwanted or defective genes; therefore a wide variety of genes and viral or nonviral vectors are being used in studies. Gene therapy strategies in cancer can be classified as inhibition of oncogene activation, activation of tumor suppressor gene, immunotherapy, suicide gene therapy and antiangiogenic gene therapy. In this review, we explain gene therapy, gene therapy strategies in cancer, approved gene medicines for cancer treatment and future of gene therapy in cancer. Today gene therapy has not yet reached the level of replacing conventional therapies. However, with a better understanding of the mechanism of cancer to determine the right treatment and target, in the future gene therapy, used as monotherapy or in combination with another existing treatment options, is likely to be used as a new medical procedure that will make cancer a controllable disease.     

Magnetic nanoparticles with surface modification enhanced gene delivery of HVJ-E vector

To enter the realm of human gene therapy, a novel drug delivery system is required for efficient delivery of small molecules with high safety for clinical usage. We have developed a unique vector "HVJ-E (hemagglutinating virus of Japan-envelope)" that can rapidly transfer plasmid DNA, oligonucleotide, and protein into cells by cell-fusion. In this study, we associated HVJ-E with magnetic nanoparticles, which can potentially enhance its transfection efficiency in the presence of a magnetic force. Magnetic nanoparticles, such as maghemite, with an average size of 29 nm, can be regulated by a magnetic force and basically consist of oxidized Fe which is commonly used as a supplement for the treatment of anemia. A mixture of magnetite particles with protamine sulfate, which gives a cationic surface charge on the maghemite particles, significantly enhanced the transfection efficiency in an in vitro cell culture system based on HVJ-E technology, resulting in a reduction in the required titer of HVJ. Addition of magnetic nanoparticles would enhance the association of HVJ-E with the cell membrane with a magnetic force. However, maghemite particles surface-coated with heparin, but not protamine sulfate, enhanced the transfection efficiency in the analysis of direct injection into the mouse liver in an in vivo model. The size and surface chemistry of magnetic particles could be tailored accordingly to meet specific demands of physical and biological characteristics. Overall, magnetic nanoparticles with different surface modifications can enhance HVJ-E-based gene transfer by modification of the size or charge, which could potentially help to overcome fundamental limitations to gene therapy in vivo.     

Blocking monoclonal antibodies of TIM proteins as orchestrators of anti-tumor immune response

Monoclonal antibody (mAb)-based treatment of cancer has a significant effect on current practice in medical oncology, and is considered now as one of the most successful therapeutic strategies for cancer treatment. MAbs are designed to initiate or enhance anti-tumor immune responses, which can be achieved by either blocking inhibitory immune checkpoint molecules or triggering activating receptors. TIM gene family members are type-I surface molecules expressed in immune cells, and play important roles in the regulation of both innate and adaptive arms of the immune system. Therapeutic strategies based on anti-TIMs mAbs have shown promising results in experimental tumor models, and synergistic combinations of anti-TIMs mAbs with cancer vaccines, adoptive T-cell therapy, radiotherapy and chemotherapy will have great impact on cancer treatment in future clinical development.     

Blocking monoclonal antibodies of TIM proteins as orchestrators of anti-tumor immune response

Monoclonal antibody (mAb)-based treatment of cancer has a significant effect on current practice in medical oncology, and is considered now as one of the most successful therapeutic strategies for cancer treatment. MAbs are designed to initiate or enhance anti-tumor immune responses, which can be achieved by either blocking inhibitory immune checkpoint molecules or triggering activating receptors. TIM gene family members are type-I surface molecules expressed in immune cells, and play important roles in the regulation of both innate and adaptive arms of the immune system. Therapeutic strategies based on anti-TIMs mAbs have shown promising results in experimental tumor models, and synergistic combinations of anti-TIMs mAbs with cancer vaccines, adoptive T-cell therapy, radiotherapy and chemotherapy will have great impact on cancer treatment in future clinical development.     

HVJ-envelope vector for gene transfer into central nervous system

To overcome some problems of virus vectors, we developed a novel non-viral vector system, the HVJ-envelope vector (HVJ-E). In this study, we investigated the feasibility of gene transfer into the CNS using the HVJ-E both in vitro and in vivo. Using the Venus reporter gene, fluorescence could be detected in cultured rat cerebral cortex neurons and glial cells. In vivo, the reporter gene (Venus) was successfully transfected into the rat brain by direct injection into the thalamus, intraventricular injection, or intrathecal injection, without inducing immunological change. When the vector was injected after transient occlusion of the middle cerebral artery, fluorescence due to EGFP gene or luciferase activity could be detected only in the injured hemisphere. Finally, luciferase activity was markedly enhanced by the addition of 50 U/ml heparin (P<0.01). Development of efficient HVJ-E for gene transfer into the CNS will be useful for research and clinical gene therapy.     

Sendai virus F glycoprotein induces IL-6 production in dendritic cells in a fusion-independent manner

We previously reported that inactivated Sendai virus particle (hemagglutinating virus of Japan envelope; HVJ-E) has anti-tumor effects by eliciting IL-6 production in dendritic cells (DCs). In the present study, we investigated which components of HVJ-E elicit IL-6 production. HVJ-E containing F0 protein inactive for virus envelope-cell membrane fusion enhanced IL-6 production. Reconstituted liposomes containing F protein stimulated IL-6 production. The antibody against F protein inhibited IL-6 secretion by HVJ-E. When carbohydrate chains of the F glycoprotein were removed, HVJ-E lost the ability to stimulate IL-6 secretion. These results suggest that F glycoprotein is required for IL-6 production in DCs.     

Oxidative stress and Nrf2 in the pathophysiology of diabetic neuropathy: old perspective with a new angle

Porcine reproductive and respiratory syndrome virus (PRRSV) is an economically detrimental pig pathogen that causes significant losses for the pig industry. The immunostimulatory effects of hemagglutinating virus of Japan envelope (HVJ-E) in cancer therapy and the adjuvant efficacy of HVJ-E have been previously evaluated. The objective of this study was to investigate the adjuvant effects of HVJ-E on immunization with killed PRRSV vaccine, and to evaluate the protective effects of this immunization strategy against virulent PRRSV infection in piglets. Next, the PRRSV-specific antibody response, lymphocyte proliferation, PRRSV-specific IL-2, IL-10 and IFN-γ production, and the overall protection efficacy were evaluated to assess the immune responses of the piglets. The results showed that the piglets inoculated simultaneously with killed PRRSV vaccine and HVJ-E had a significantly stronger immune response than those inoculated with killed PRRSV vaccine alone. Our results suggest that HVJ-E could be employed as an effective adjuvant to enhance the humoral and cellular responses of piglets to PRRSV.     

Intratumoral injection of inactivated Sendai virus particles elicits strong antitumor activity by enhancing local CXCL10 expression and systemic NK cell activation

We have already demonstrated that inactivated, replication-defective Sendai virus particles (HVJ-E) have a powerful antitumor effect by both the generation of tumor-specific cytotoxic T cells and inhibition of regulatory T cell activity. Here, we report that HVJ-E also has an antitumor effect through non-T cell immunity. Microarray analysis revealed that direct injection of HVJ-E induced the expression of CXCL10 in established Renca tumors. CXCL10 was secreted by dendritic cells in the tumors after HVJ-E injection. Quantitative real-time RT-PCR and immunohistochemistry revealed that CXCR3+ cells (predominantly NK cells) infiltrated the HVJ-E-injected tumors. Moreover, HVJ-E injection caused systemic activation of NK cells and enhanced their cytotoxity against tumor cells. In an in vivo experiment, approximately 50% of tumors were eradicated by HVJ-E injection, and this activity of HVJ-E against Renca tumors was largely abolished by NK cell depletion using anti-asialo GM1 antibody. Since HVJ-E injection induced systemic antitumor immunity by enhancing or correcting the chemokine-chemokine receptor axis, it might be a potential new therapy for cancer.     

A single intratumoral injection of a fiber-mutant adenoviral vector encoding interleukin 12 induces remarkable anti-tumor and anti-metastatic activity in mice with Meth-A fibrosarcoma

Cytokine-encoding viral vectors are considered to be promising in cancer gene immunotherapy. Interleukin 12 (IL-12) has been used widely for anti-tumor treatment, but the administration route and tumor characteristics strongly influence therapeutic efficiency. Meth-A fibrosarcoma has been demonstrated to be insensitive to IL-12 treatment via systemic administration. In the present study, we developed an IL-12-encoding fiber-mutant adenoviral vector (AdRGD-IL-12) that showed enhanced gene transfection efficiency in Meth-A tumor cells, and the production of IL-12 p70 in the culture supernatant from transfected cells was confirmed by ELISA. In therapeutic experiments, a single low-dose (2 x 10(7) plaque-forming units) intratumoral injection of AdRGD-IL-12 elicited pronounced anti-tumor activity and notably prolonged the survival of Meth-A fibrosarcoma-bearing mice. Immunohistochemical staining revealed that the IL-12 vector induced the accumulation of T cells in tumor tissue. Furthermore, intratumoral administration of the vector induced an anti-metastasis effect as well as long-term specific immunity against syngeneic tumor challenge.     

Cell Culture Processes for the Production of Viral Vectors for Gene Therapy Purposes

Gene therapy is a promising technology for the treatment of several acquired and inherited diseases. However, for gene therapy to be a commercial and clinical success, scalable cell culture processes must be in place to produce the required amount of viral vectors to meet market demand. Each type of vector has its own distinct characteristics and consequently its own challenges for production. This article reviews the current technology that has been developed for the efficient, large-scale manufacture of retrovirus, lentivirus, adenovirus, adeno-associated virus and herpes simplex virus vectors.     

Gene therapy of cardiovascular disorders

More than 300 protocols have been developed for human gene therapy, but, it has not yet been proved to be a successful therapeutic strategy. One of the most important barriers to success is the development of efficient gene delivery systems. We have developed HVJ-liposomes by combining fusion proteins of HVJ (Hemagglutinating virus of Japan; Sendai virus) with liposomes containing DNA. This vector system has been very effective for in vivo gene delivery, especially in cardiovascular systems. Using HVJ-liposomes, we have reported successful gene therapy experiments such as prevention of restenosis after balloon injury, suppression of dysfunction of vein graft, and experimental ischemic disorders. Indeed, the success in the treatment of arteriosclerosis obliterance by VEGF (vascular endothelial growth factor) gene transfer was reported recently. These cardiovascular gene therapy strategies appear to be very promising therapeutics in future.     

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.