Production of adenovirus vector for gene therapy

The field of gene therapy is rapidly expanding with a major focus on the treatment of cancer. Replication-defective adenoviruses are vectors of choice for delivering corrective genes into human cells. Major efforts are directed to design new generations of adenoviral vectors that feature reduced immunogenicity and improved targeting ability. However, the production of adenoviral vectors for gene therapy applications faces a number of challenges that limit the availability of high quality material at the early stages of research and development in the gene therapy field. Moreover, very few papers have been published on the subject and information on large-scale production methods are only available through specialized conference proceedings. This review outlines the problems associated with mass production of adenovirus vectors and describes research efforts by a number of groups who have contributed to optimize production methods. Better understanding of the adenovirus infection and replication kinetics as well as better understanding of complementing cell line physiology and metabolism greatly contributed to improving vector titers and volumetric productivity at higher cell densities. Also, the critical aspect of viral vector quantitation is discussed.     

Tumor-specific, replication-competent adenovirus vectors overexpressing the adenovirus death protein

We have constructed two novel adenovirus (Ad) replication-competent vectors, named KD1 and KD3, that may have use in anticancer therapy. The vectors have two key features. First, they markedly overexpress the Ad death protein (ADP), an Ad nuclear membrane glycoprotein required at late stages of infection for efficient cell lysis and release of Ad from cells. Overexpression of ADP was achieved by deleting the E3 region and reinserting the adp gene. Because ADP is overexpressed, KD1 and KD3 are expected to spread more rapidly and effectively through tumors. Second, KD1 and KD3 have two E1A mutations (from the mutant dl1101/1107) that prevent efficient replication in nondividing cells but allow replication in dividing cancer cells. These E1A mutations preclude binding of E1A proteins to p300 and pRB. As a result, the virus should not be able to drive cells from G(0) to S phase and therefore should not be able to replicate in normal tissues. We show that KD1 and KD3 do not replicate well in quiescent HEL-299 cells or in primary human bronchial epithelial cells, small airway epithelial cells, or endothelial cells; however, they replicate well in proliferating HEL-299 cells and human A549 lung carcinoma cells. In cultured A549 cells, KD1 and KD3 lyse cells and spread from cell to cell more rapidly than their control virus, dl1101/1107, or wild-type Ad. They are also more efficient than dl1101/1107 or wild-type Ad in complementing the spread from cell to cell of an E1(-) E3(-) replication-defective vector expressing beta-galactosidase. A549 cells form rapidly growing solid tumors when injected into the hind flanks of immunodeficient nude mice; however, when A549 cells were infected with 10(-4) PFU of KD3/cell prior to injection into mice, tumor formation was nearly completely suppressed. When established A549 tumors in nude mice were examined, tumors injected with buffer grew 13.3-fold over 5 weeks, tumors injected with dl1101/1107 grew 8-fold, and tumors injected with KD1 or KD3 grew 2.6-fold. Hep 3B tumors injected with buffer grew 12-fold over 3.5 weeks, whereas tumors injected with KD1 or KD3 grew 4-fold. We conclude that KD1 and KD3 show promise as anticancer therapeutics.     

GM-CSF-armed,replication-competent viruses for cancer

Monoclonal antibody therapy for cancer has significantly altered the natural history of several common cancers. This success was attained only after many years of failure to understand the technical limitations of antibody therapy. In order to further exploit the immune system, tumor vaccine strategies are an active research focus. Virus based immune agents including GM-CSF armed vectors are among these early efforts. Herpes, adenovirus, and vaccinia based vectors encoding GM-CSF have reported intriguing early clinical trial results that are reviewed here.     

肿瘤基因治疗中腺病毒载体改造热点

在病毒介导的肿瘤基因治疗的研究中,腺病毒具有多种优点使其成为基因治疗中使用最多的载体之一.但腺病毒也存在许多问题迫使科学家们去不断的优化它,以达到更好的治疗效果.其中对腺病毒外壳蛋白的改造、对腺病毒基因组的改造以及使用化学修饰剂对腺病毒进行修饰改造一直是研究的热点,本文就对腺病毒改造的热点研究及取得的新成果作一评述.     

Potential of adenovirus as a vector for sustained gene expression

Inder Verma received his Ph.D. in biochemistry from the Weizmann Institute of Science, Rehovot, Israel, in 1971, and was a postdoctoral fellow (with David Baltimore) in the Department of Biology, Massachussetts Institute of Technology. He is currently American Cancer Society Professor of Molecular Biology, Chair of the Laboratory of Genetics at the Salk Institute for Biological Studies, and Adjunct Professor in the Department of Biology, University of California at San Diego. Inder Verma is a member of the National Academy of Sciences (USA). He is a member of the editorial boards of The Journal of Gene Medicine, Journal of Virology and Gene, and serves on several other scientific advisory boards. His major fields of interest are molecular analysis of oncoproteins, and suppressor genes, gene therapy involving retroviral, adenoviral, AAV vectors, and generation of novel lentiviral vectors. Copyright © 1999 John Wiley & Sons, Ltd.     

Yaba-like disease virus: an alternative replicating poxvirus vector for cancer gene therapy

Vaccinia virus is being investigated as a replicating vector for tumor-directed gene therapy. However, the majority of cancer patients have preformed immunologic reactivity against vaccinia virus, as a result of smallpox vaccination, which may limit its use as a vector. The Yaba-like disease (YLD) virus was investigated here as an alternative, replicating poxvirus for cancer gene therapy. We have demonstrated that the YLD virus does not cross-react with vaccinia virus antibodies, and it replicates efficiently in human tumor cells. YLD virus can be expanded and purified to high titer in CV-1 cells under conditions utilized for vaccinia virus. The YLD virus RNA polymerase was able to express genes regulated by a synthetic promoter designed for use in orthopoxviruses. We sequenced the YLD virus TK gene and created a shuttle plasmid, which allowed the recombination of the green fluorescent protein (GFP) gene into the YLD virus. In a murine model of ovarian cancer, up to 38% of cells in the tumor expressed the GFP transgene 12 days after intraperitoneal virus delivery. YLD virus has favorable characteristics as a vector for cancer gene therapy, and this potential should be explored further.     

Cancer screening by systemic administration of a gene delivery vector encoding tumor-selective secretable biomarker expression

Cancer biomarkers facilitate screening and early detection but are known for only a few cancer types. We demonstrated the principle of inducing tumors to secrete a serum biomarker using a systemically administered gene delivery vector that targets tumors for selective expression of an engineered cassette. We exploited tumor-selective replication of a conditionally replicative Herpes simplex virus (HSV) combined with a replication-dependent late viral promoter to achieve tumor-selective biomarker expression as an example gene delivery vector. Virus replication, cytotoxicity and biomarker production were low in quiescent normal human foreskin keratinocytes and high in cancer cells in vitro. Following intravenous injection of virus >90% of tumor-bearing mice exhibited higher levels of biomarker than non-tumor-bearing mice and upon necropsy, we detected virus exclusively in tumors. Our strategy of forcing tumors to secrete a serum biomarker could be useful for cancer screening in high-risk patients, and possibly for monitoring response to therapy. In addition, because oncolytic vectors for tumor specific gene delivery are cytotoxic, they may supplement our screening strategy as a "theragnostic" agent. The cancer screening approach presented in this work introduces a paradigm shift in the utility of gene delivery which we foresee being improved by alternative vectors targeting gene delivery and expression to tumors. Refining this approach will usher a new era for clinical cancer screening that may be implemented in the developed and undeveloped world.     

Gene delivery into neuronal and glial cells by using a replication-deficient adenovirus vector: prospects for neurological gene therapy

We have used a recombinant adenovirus vector (E1−) expressing β-galactosidase to explore a novel mechanism with which to transfer genes into cells of the central nervous system (CNS). The replication-deficient adenovirus vector expressing β-galactosidase (RAd35) was propagated on a permissive helper cell line (293 cells). High level protein expression from the human cytomegalovirus immediate early promoter (hCMV IE) was obtained in a target cell population of RAd35 infected cultured neuronal and glial cell lines. Light microscopy showed that over 50% of the glial cells studied expressed β-galactosidase. Following retinoic acid treatment, RAd35 infected cell lines ND7/23, NG108 and NTera2, showed β-galactosidase expression in up to 90% of the cells. In addition, these cells showed morphological evidence of differentiation into neurons. This pattern of β-galactosidase expression was also observed in primary rat cerebella granule neuron cultures. In vivo studies were performed in Balb/c mice following direct intracranial injections of RAd35 into the brain. Cell sections showed a localised staining in the brain at the site of injection of the virus. Non-replicating adenovirus vectors are therefore highly efficient systems for delivering a transgene into brain cells. However, their broad cell tropism may limit their applications for genetic disorders in which a specific cell type is to be targeted for gene therapy. To address this problem, we have constructed adenovirus vectors which contain specific neuronal promoters and are currently assessing in vitro expression. This revised version was published online in July 2006 with corrections to the Cover Date.     

The use of Listeria monocytogenes as a DNA delivery vector for cancer gene therapy

Listeria monocytogenes is an intracellular pathogen that lyses the phagosomal vacuole of infected cells, proliferates in the host cell cytoplasm and can actively enter adjacent cells. The pathogen is therefore well suited to exploitation as a vector for the delivery of DNA to target cells as the lifecycle favors cellular targeting with vector amplification and the potential for cell-to-cell spread. We have recently demonstrated DNA transfer by L. monocytogenes in growing tumors in murine models. Our approach exploited an ampicillin sensitive stain of L. monocytogenes which can be lysed through systemic administration of ampicillin to facilitate release of plasmid DNA for expression by infected mammalian cells. Here, we discuss the implications of this technology and the potential for future improvements of the system.     

Genomic and bioinformatics analysis of HAdV-4, a human adenovirus causing acute respiratory disease: implications for gene therapy and vaccine vector development

Human adenovirus serotype 4 (HAdV-4) is a reemerging viral pathogenic agent implicated in epidemic outbreaks of acute respiratory disease (ARD). This report presents a genomic and bioinformatics analysis of the prototype 35,990-nucleotide genome (GenBank accession no. AY594253). Intriguingly, the genome analysis suggests a closer phylogenetic relationship with the chimpanzee adenoviruses (simian adenoviruses) rather than with other human adenoviruses, suggesting a recent origin of HAdV-4, and therefore species E, through a zoonotic event from chimpanzees to humans. Bioinformatics analysis also suggests a pre-zoonotic recombination event, as well, between species B-like and species C-like simian adenoviruses. These observations may have implications for the current interest in using chimpanzee adenoviruses in the development of vectors for human gene therapy and for DNA-based vaccines. Also, the reemergence, surveillance, and treatment of HAdV-4 as an ARD pathogen is an opportunity to demonstrate the use of genome determination as a tool for viral infectious disease characterization and epidemic outbreak surveillance: for example, rapid and accurate low-pass sequencing and analysis of the genome. In particular, this approach allows the rapid identification and development of unique probes for the differentiation of family, species, serotype, and strain (e.g., pathogen genome signatures) for monitoring epidemic outbreaks of ARD.