Stem Cell-Based Cell Carrier for Targeted Oncolytic Virotherapy: Translational Opportunity and Open Questions

Oncolytic virotherapy for cancer is an innovative therapeutic option where the ability of a virus to promote cell lysis is harnessed and reprogrammed to selectively destroy cancer cells. Such treatment modalities exhibited antitumor activity in preclinical and clinical settings and appear to be well tolerated when tested in clinical trials. However, the clinical success of oncolytic virotherapy has been significantly hampered due to the inability to target systematic metastasis. This is partly due to the inability of the therapeutic virus to survive in the patient circulation, in order to target tumors at distant sites. An early study from various laboratories demonstrated that cells infected with oncolytic virus can protect the therapeutic payload form the host immune system as well as function as factories for virus production and enhance the therapeutic efficacy of oncolytic virus. While a variety of cell lineages possessed potential as cell carriers, copious investigation has established stem cells as a very attractive cell carrier system in oncolytic virotherapy. The ideal cell carrier desire to be susceptible to viral infection as well as support viral infection, maintain immunosuppressive properties to shield the loaded viruses from the host immune system, and most importantly possess an intrinsic tumor homing ability to deliver loaded viruses directly to the site of the metastasis—all qualities stem cells exhibit. In this review, we summarize the recent work in the development of stem cell-based carrier for oncolytic virotherapy, discuss the advantages and disadvantages of a variety of cell carriers, especially focusing on why stem cells have emerged as the leading candidate, and finally propose a future direction for stem cell-based targeted oncolytic virotherapy that involves its establishment as a viable treatment option for cancer patients in the clinical setting.     

Room for improvement in the treatment of pancreatic cancer: Novel opportunities from gene targeted therapy

Pancreatic cancer is one of the highest and in fact, unchanged mortality-associated tumor, with an exceptionally low survival rate due to its challenging diagnostic approach. So far, its treatment is based on a combination of approaches (such as surgical resection with or rarely without chemotherapeutic agents), but with finite limits. Thus, looking for additional space to improve pancreatic tumorigenesis therapeutic approach, research has focused on gene therapy with unexpectedly growing horizons not only for the treatment of inoperable pancreatic disease, but also for its early stages. In vivo gene delivery viral vectors, despite few disadvantages (possible immunogenicity, toxicity, mutagenicity, or high cost), could be one of the most efficient cancer gene therapeutic strategies for clinical application due to their superiority compared with other systems (ex vivo delivery strategies). Their dominance consists of simple preparation, easy operation and a wide range of functions. Adenoviruses are one of the most common used vectors, inducing strong immune as well as inflammatory reactions. Oncolytic virotherapy, using the above mentioned in vivo viral vectors, is one of the most promising non-pathogenic, highly-selective cytotoxic anti-cancer therapy using anti-cancer agents with high anti-tumor potency and strong oncolytic effect. There have been a variety of targeted therapeutic and pre-clinical strategies tested for gene therapy in pancreatic cancer such as gene-editing systems (e.g., clustered regularly interspaced palindromic repeats-Cas9), RNA interference technology (e.g., microRNAs, short hairpin RNA or small interfering RNA), adoptive immunotherapy and vaccination (e.g., chimeric antigen receptor T-cell therapy) with encouraging results.     

Serotype chimeric human adenoviruses for cancer gene therapy

Cancer gene therapy consists of numerous approaches where the common denominator is utilization of vectors for achieving therapeutic effect. A particularly potent embodiment of the approach is virotherapy, in which the replication potential of an oncolytic virus is directed towards tumor cells to cause lysis, while normal cells are spared. Importantly, the therapeutic effect of the initial viral load is amplified through viral replication cycles and production of progeny virions. All cancer gene therapy approaches rely on a sufficient level of delivery of the anticancer agent into target cells. Thus, enhancement of delivery to target cells, and reduction of delivery to non-target cells, in an approach called transductional targeting, is attractive. Both genetic and non-genetic retargeting strategies have been utilized. However, in the context of oncolytic viruses, it is beneficial to have the specific modification included in progeny virions and hence genetic modification may be preferable. Serotype chimerism utilizes serotype specific differences in receptor usage, liver tropism and seroprevalence in order to gain enhanced infection of target tissue. This review will focus on serotype chimeric adenoviruses for cancer gene therapy applications.     

Adenoviral gene therapy in gastric cancer： A review

Gastric cancer is one of the most common malignancies worldwide. With current therapeutic approaches the prognosis of gastric cancer is very poor, as gastric cancer accounts for the second most common cause of death in cancer related deaths. Gastric cancer like almost all other cancers has a molecular genetic basis which relies on disruption in normal cellular regulatory mechanisms regarding cell growth, apoptosis and cell division. Thus novel therapeutic approaches such as gene therapy promise to become the alternative choice of treatment in gastric cancer. In gene therapy, suicide genes, tumor suppressor genes and anti-angiogenesis genes among many others are introduced to cancer cells via vectors. Some of the vectors widely used in gene therapy are Adenoviral vectors. This review provides an update of the new developments in adenoviral cancer gene therapy including strategies for inducing apoptosis, inhibiting metastasis and targeting the cancer cells.     

Bacteriophage-Derived Vectors for Targeted Cancer Gene Therapy

Cancer gene therapy expanded and reached its pinnacle in research in the last decade. Both viral and non-viral vectors have entered clinical trials, and significant successes have been achieved. However, a systemic administration of a vector, illustrating safe, efficient, and targeted gene delivery to solid tumors has proven to be a major challenge. In this review, we summarize the current progress and challenges in the targeted gene therapy of cancer. Moreover, we highlight the recent developments of bacteriophage-derived vectors and their contributions in targeting cancer with therapeutic genes following systemic administration.     

Gene therapy for gastric cancer： Is it promising？

Gastric cancer is one of the most common tumorsworldwide.The therapeutic outcome of conventionaltherapies is inefficient.Thus,new therapeutic strategiesare urgently needed.Gene therapy is a promisingmolecular alternative in the treatment of gastric cancer,including the replacement of defective tumor suppressorgenes,the inactivation of oncogenes,the introduction ofsuicide genes,genetic immunotherapy,anti-angiogeneticgene therapy,and virotherapy.Improved molecularbiological techniques and a better understanding ofgastric carcinogenesis have allowed us to validate avariety of genes as molecular targets for gene therapy.This review provides an update of the new developmentsin cancer gene therapy,new principles,techniques,strategies and vector systems,and shows how they maybe applied in the treatment of gastric cancer.     

Targeting adeno-associated virus and adenoviral gene therapy for hepatocellular carcinoma

Human hepatocellular carcinoma (HCC) heavily endangers human heath worldwide. HCC is one of most frequent cancers in China because patients with liver disease, such as chronic hepatitis, have the highest cancer susceptibility. Traditional therapeutic approaches have limited efficacy in advanced liver cancer, and novel strategies are urgently needed to improve the limited treatment options for HCC. This review summarizes the basic knowledge, current advances, and future challenges and prospects of adeno-associated virus (AAV) and adenoviruses as vectors for gene therapy of HCC. This paper also reviews the clinical trials of gene therapy using adenovirus vectors, immunotherapy, toxicity and immunological barriers for AAV and adenoviruses, and proposes several alternative strategies to overcome the therapeutic barriers to using AAV and adenoviruses as vectors.     

Current status of gene therapy for hemophilia

The hemophilias are an attractive model for gene therapy because their clinical manifestations are attributable to the lack of a single protein that circulates in minute amounts in the plasma. Sustained therapeutic expression of factors VIII and IX has been achieved in preclinical studies using a wide range of gene transfer technologies targeted at different tissues. This achievement has led to six different phase I/II clinical trials that resulted in limited efficacy but minimal toxicity. Recombinant adeno-associated viral vectors appear most promising for hemophilia gene therapy; however, this review summarizes all the major gene therapy approaches used and outlines the future challenges.     

Gene therapy for gastrointestinal tract cancer: a review

Carcinomas of the gastrointestinal tract count as one of the most common causes of cancer-related death in the world. Despite improvement of conventional treatment modalities, the prognosis of patients with gastrointestinal tract cancer remains poor. Progress in understanding the molecular mechanism of gastrointestinal carcinogenesis may facilitate development of gene therapy strategies for the treatment of gastrointestinal tumors. This review describes new developments in vectors (tools for gene transfer) for gene therapy, possible therapeutic genes and the early clinical results of gastrointestinal tract cancer gene therapy. Results of current preclinical studies are promising for the future clinical application of gene therapy for gastrointestinal cancer. The first clinical trials have been initiated recently, the preliminary results reflecting low toxicity and clinical responses. Further clinical studies will be required to confirm the feasibility of gene therapy in the treatment of gastrointestinal cancer. In future, the greatest potential will probably lie in the field of combination strategies of gene therapy and existing treatment modalities, such as surgery combined with molecular chemotherapy.     

Gene therapy of pituitary diseases

Despite a stuttering course, gene therapy continues to provide a potential treatment avenue for many human diseases, including cancer and various inherited disorders. Gene therapy is also attractive for the treatment of local, benign disorders, such as pituitary adenomas. Advances in technology have focused on modifying existing viral vectors and developing targeted expression of therapeutic genes in an effort to achieve efficacy with minimal toxicity. Gene therapy also offers innovative strategies for treating hypopituitarism by replacing hormones such as growth hormone (GH) and vasopressin.     

Anti-HIV-1 gene expressing lentiviral vectors as an adjunctive therapy for HIV-1 infection

Lentiviral based gene therapy may provide a valuable addition to the current anti-HIV arsenal. Many lentiviral vector systems have been described including those based on feline immunodeficiency virus (FIV), human immunodeficiency virus 1 (HIV) and 2 (HIV-2/SIV) as well as replication incompetent, self-inactivating (sin) vs. conditionally replicating (mobilizable) vectors. Lentiviral vectors offer promise in treating HIV-1 infection as they are capable of stably transducing both dividing and nondividing cells, specifically those cells involved in HIV-1 replication and immune restoration: T-cells, hematopoietic stem cells, and dendritic cells. Moreover, some of the HIV-1 and 2 based vectors can be mobilized by wildtype HIV-1 in vivo and spread to those cells targeted by the virus as well as can compete with viral RNA for packaging and access to viral proteins such as Tat and Rev required for viral replication. Finally, lentiviral vectors can be designed to express therapeutic anti-HIV-1 genes, which specifically target various stages of viral replication. Many candidate RNA based anti-HIV-1 genes have been expressed from lentiviral vectors including ribozymes and anti-sense RNA [1]. Recently, small interfering RNAs (siRNAs) have been shown to potently suppress HIV replication [2-6]. This review will focus on the current status of lentiviral vector development and the feasibility of using lentiviral vectors in delivering anti-HIV genes, specifically ribozymes, and siRNAs as a therapeutic approach to employ in conjunction with current anti-retroviral therapies.     

Review: Gene Therapy for Cancer:

Gene therapy is a new form of therapeutic intervention with applications in many areas of medical treatment. There are still many technical difficulties to be overcome, but recent advances in the molecular and cellular biology of gene transfer have made it likely that gene therapy will soon start to play an increasing role in clinical practice and particularly in the treatment of cancer. The first clinical gene transfer in an approved protocol took place exactly 10 years ago, and it was for the transfer of gene-marked immune cells into patients with advanced cancer. Now there are 218 active clinical protocols in the United States, and they have involved over 2000 patients worldwide. Among the conditions and diseases for which gene transfer is being tried as treatment, cancer comes first with 130 clinical trials. Fundamental research in the mechanisms of cancer and the development of molecular biology tools are crucial for the success of the treatments in the future. The identification of tumor rejection antigens from a variety of cancers and the immune response that is defective in cancer patients are important topics for future studies. The evaluation of gene therapy combinations involving use of tumor suppressor genes and constructs that inactivate oncogenes is also another important area for future research. The future improvement of present viruses as well as the use of new viral vectors will likely expand the applicability and efficacy of gene therapy. During the next decade technological developments, particularly in the areas of gene delivery and cell transplantation, will be critical for the successful clinical practice of gene therapy.     

Changing strategies for target therapy in gastric cancer

In spite of a worldwide decrease in the incidence of gastric cancer, this malignancy still remains one of the leading causes of cancer mortality. Great efforts have been made to improve treatment outcomes in patients with metastatic gastric cancer, and the introduction of trastuzumab has greatly improved the overall survival. The trastuzumab treatment took its first step in opening the era of molecular targeted therapy, however several issues still need to be resolved to increase the efficacy of targeted therapy. Firstly, many patients with metastatic gastric cancer who receive trastuzumab in combination with chemotherapeutic agents develop resistance to the targeted therapy. Secondly, many clinical trials testing novel molecular targeted agents with demonstrated efficacy in other malignancies have failed to show benefit in patients with metastatic gastric cancer, suggesting the importance of the selection of appropriate indications according to molecular characteristics in application of targeted agents. Herein, we review the molecular targeted agents currently approved and in use, and clinical trials in patients with metastatic gastric cancer, and demonstrate the limitations and future direction in treatment of advanced gastric cancer.     

Gene therapy for haemophilia…yes,but…with non‐viral vectors?

Summary. High‐purity plasma‐derived and recombinant factors are currently safe and efficient treatment for haemophilia. The mid‐term future of haemophilia treatment will involve the use of modified recombinant factors to achieve advantages such as decreased immunogenicity in inhibitor formation and enhanced efficacy as a result of their longer half‐life. In the long‐term, gene therapy and cell therapy strategies will have to be considered. Achievements in cell therapy to date have been using embryonic stem cells and hepatic sinusoidal endothelial cells. Current gene therapy strategies for haemophilia are based on gene transfer using adeno‐associated viruses and non‐viral vectors. Gene therapy for haemophilia is justified because it is a chronic disease and because a very regular factor infusion is required that may involve fatal risks and because it is very expensive. Haemophilia is a very good candidate for use of gene therapy protocols because it is a monogenic disease, and even low expression is able to achieve reversion from a severe to a moderate phenotype. The current trends in haemophilia using adeno‐associated viral vectors are safe but also involve immunogenicity problems. The other alternatives are non‐viral vectors. There have been in recent years relevant advances in non‐viral transfection that raise hope for considering this possibility. Several research groups are opting for this experimental alternative. An expression over 5%, representing a moderate phenotype, for a few months with a high safety, regarding vector, transfected cells, and implantation procedure, would already be a great success. This may represent an intermediate protocol in which the expression levels and times obtained are lower and shorter respectively as compared to viral vectors, but which provide a potential greater patient safety. This may more readily win acceptance among both patients and haematologists because fatal events in the past due to HIV/HCV infection may constrain the implementation of viruses as vectors.     

Molecular therapy in a model neuroendocrine disease: developing clinical gene therapy for pituitary tumours.

The main objectives of pituitary tumour treatment are to restore normal function of the pituitary gland and prevent tumour recurrences. In spite of the success of current therapies in the treatment of relatively small tumours, new therapeutic alternatives need to be explored for large invasive tumours, tumour recurrences postsurgery, and when intolerance to drug treatment develops. Gene therapy, which uses nucleic acids as drugs, is a very attractive alternative to classic therapeutic modalities. With the development of efficient gene delivery vectors, which allow widespread distribution and long-term transgene expression with limited side effects, the clinical implementation of gene therapy for the treatment of pituitary tumours will become a reality within the next five to ten years.     

Cardiac Gene Therapy: From Concept to Reality

Heart failure is increasing in incidence throughout the world, especially in industrialized countries. Although the current therapeutic modalities have been successful in stabilizing the course of heart failure, morbidity and mortality remain quite high and there remains a great need for innovative breakthroughs that will offer new treatment strategies for patients with advanced forms of the disease. The past few years have witnessed a greater understanding of the molecular underpinnings of the failing heart, paving the way for novel strategies in modulating the cellular environment. As such, gene therapy has recently emerged as a powerful tool offering the promise of a new paradigm for alleviating heart failure. Current gene therapy research for heart failure is focused on exploring potential cellular targets and preclinical and clinical studies are ongoing toward the realization of this goal. Efforts also include the development of sophisticated viral vectors and vector delivery methods for efficient transduction of cardiomyocytes.     

New therapeutic opportunities for hepatitis C based on small RNA

Hepatitis C virus (HCV) infection is one of the major causes of chronic liver disease, including cirrhosis and liver cancer and is therefore, the most common indication for liver transplantation. Conventional antiviral drugs such as pegylated interferon-alpha, taken in combination with ribavirin, represent a milestone in the therapy of this disease. However, due to different viral and host factors, clinical success can be achieved only in approximately half of patients, making urgent the requirement of exploiting alternative approaches for HCV therapy. Fortunately, recent advances in the understanding of HCV viral replication and host cell interactions have opened new possibilities for therapeutic intervention. The most recent technologies, such as small interference RNA mediated gene-silencing, anti-sense oligonucleotides (ASO), or viral vector based gene delivery systems, have paved the way to develop novel therapeutic modalities for HCV. In this review, we outline the application of these technologies in the context of HCV therapy. In particular, we will focus on the newly defined role of cellular microRNA (miR-122) in viral replication and discuss its potential for HCV molecular therapy.