Effective Gene Transfer into Regenerating Sciatic Nerves by Adenoviral Vectors: Potentials for Gene Therapy of Peripheral Nerve Injury

Replication defective adenoviral vectors have been demonstrated as an effective method for delivering genes into a variety of cell types and tissues both in vivo and in vitro. Transfecting genes into neuronal cells has proven to be difficult because of their lack of cell division. Since the major problem in neurological disease is the degeneration of the terminally differentiated neuronal cells, the adenoviral vectors ability to transfer genes into differentiated post-mitotic cells makes them advantageous for a gene delivery system for the nervous system. Here we showed that a replication defective recombinant adenovirus carrying the lacZ gene could infect the neuronal stem cells and even the differentiated neuronal cells derived from the central nervous system. The lacZ gene delivered into the neuronal cells was expressed efficiently. In addition, the recombinant virus also infected Schwann cells in intact and injured nerves in vivo. The expression of the lacZ gene lasted for 5 weeks, within which nerve regeneration is accomplished in the rat. Adenoviral vectors might thus be used to modulate Schwann cell gene expression for treating peripheral nerve injury or peripheral neuropathy.     

Imaging gene expression in the brain with peptide nucleic acid (PNA) antisense radiopharmaceuticals and drug targeting technology

Summary Antisense oligomers are potential pharmaceutical and radiopharmaceutical agents that can be used to modulate and image gene expression. Progress within vivo gene targeting using antisense-based therapeutics has been slower than expected during the last decade, owing to poor trans-cellular delivery of antisense agents. This chapter suggests that if antisense pharmacology is merged with drug targeting technology, then membrane barriers can be circumvented and antisense agents can be delivered to tissuesin vivo. Without the application of drug targeting, the likelihood of success for an antisense drug development program is low, particularly for the brain which is protected by the blood-brain barrier (BBB). Among the different classes of antisense agents, peptide nucleic acids (PNA) present advantages forin vivo applications over conventional and modified oligodeoxynucleotides (ODN), including phosphorothioates (PS)-ODN. Some advantages of PNAs include their electrically neutral backbone, low toxicity to neural cells, resistance to nucleases and peptidases, and lack of binding to plasma proteins. PNAs are poorly transported through cellular membranes, however, including the BBB and the brain cell membrane (BCM). Because the mRNA target for the antisense agent lies within the cytosol of the target cell, the BBB and the BCM must be circumventedin vivo, which is possible with the use of chimeric peptide drug targeting technology. Chimeric peptides are formed by conjugation of a non-transportable drug, such as a PNA, to a drug delivery vector. The vector undergoes receptor-mediated transcytosis (RMT) through the BBB and receptor-mediated endocytosis through the BCMin vivo. When labeled with a radioisotope (e.g.,¹²⁵I or¹¹¹In), the antisense chimeric peptide provides imaging of gene expression in the brainin vivo in a sequence-specific manner. Further development of antisense radiopharmaceutical agents may allow forin vivo imaging of genes in pathological states, and may provide tools for the analysis of novel genes with functional genomics.     

Polymer based cardiovascular gene therapy

Therapeutic angiogenesis is a new potential treatment in cardiovascular disease. It is performed by the delivery of the angiogenic agents (protein, gene). Most important consideration for gene therapy is the construction of an effective therapeutic gene. Currently, VEGF is the most effective therapeutic gene for the neovascularization. We constructed the hypoxia-regulated VEGF plasmid using the Epo enhancer and RTP801 promoter. The efficiency of the pEpo-SV-VEGF and pRTP801-VEGF were evaluated by various methodsin vitro andin vivo. The results suggested that the hypoxia-inducible VEGF gene therapy system is effective and safe, which may be useful for the gene therapy of ischemic heart disease. Development of a safe and efficient gene carrier is another main requirement for successful gene therapy. Although viralbased gene delivery is currently the most effective way to transfer genes to cells, nonviral vectors are increasingly being considered forin vivo gene delivery. The advantages of nonviral gene therapy are lack of specific immunogenecity, simplicity of use, and ease of large-scale production. In addition, the simple conjugation of a targeting moiety to nonviral gene carrier can facilitate tissue-targeting gene delivery. We have developed two new gene carrier systems, TerplexDNA and WSLP (water soluble lipopolymer). These two are efficient carrier to ischemic myocardium and has low toxicity and high transfection efficiency. So it may allow for application ofin vivo gene therapy in the treatment of heart disease.     

Adenovirus as a System for Delivering and Expressing Tumor Suppressor Genes in Tumor Cells

The strategy for tumor suppressor gene therapy for cancer is to suppress the malignant phenotype of tumor cells by replacing the inactivated gene with a normal (wild-type) one to restore control of cell growth and differentiation. To effectively carry out this strategy, the therapeutic genes must be delivered efficiently and expressed at an adequate level in the tumor. Adenoviral vectors have rapidly developed into one of the major systems now in use to effect this delivery and expression, primarily because of their advantages over other viral vectors, such as their ease of manipulation, their wide host cell range with high infectivity, their relative stability with high obtainable titers (10¹⁰–10¹²plaque-forming units/ml), and their episomal expression with low genotoxicity. Adenoviral vectors are a good technical approach to delivering tumor suppressor genes for cancer therapy; they have demonstrated effectiveness in preclinical animal models. This chapter organizes and describes a series of methods for developing a preclinical model for adenovirus-mediated tumor suppressor gene therapy of cancer. The disadvantages of adenoviral vectors and the possibilities for improving this vector system to enhance tumor suppression efficacy are also discussed.     

Imaging gene expression in the brain with peptide nucleic acid (PNA) antisense radiopharmaceuticals and drug targeting technology

Summary Antisense oligomers are potential pharmaceutical and radiopharmaceutical agents that can be used to modulate and image gene expression. Progress with in vivo gene targeting using antisense-based therapeutics has been slower than expected during the last decade, owing to poor trans-cellular delivery of antisense agents. This chapter suggests that if antisense pharmacology is merged with drug targeting technology, then membrane barriers can be circumvented and antisense agents can be delivered to tissues in vivo. Without the application of drug targeting, the likelihood of success for an antisense drug development program is low, particularly for the brain which is protected by the blood-brain barrier (BBB). Among the different classes of antisense agents, peptide nucleic acids (PNA) present advantages for in vivo applications over conventional and modified oligodeoxynucleotides (ODN), including phosphorothioates (PS)-ODN. Some advantages of PNAs include their electrically neutral backbone, low toxicity to neural cells, resistance to nucleases and peptidases, and lack of binding to plasma proteins. PNAs are poorly transported through cellular membranes, however, including the BBB and the brain cell membrane (BCM). Because the mRNA target for the antisense agent lies within the cytosol of the target cell, the BBB and the BCM must be circumvented in vivo, which is possible with the use of chimeric peptide drug targeting technology. Chimeric peptides are formed by conjugation of a non-transportable drug, such as a PNA, to a drug delivery vector. The vector undergoes receptor-mediated transcytosis (RMT) through the BBB and receptor-mediated endocytosis through the BCM in vivo. When labeled with a radioisotope (e.g., ¹²⁵I or ¹¹¹In), the antisense chimeric peptide provides imaging of gene expression in the brain in vivo in a sequence-specific manner. Further development of antisense radiopharmaceutical agents may allow for in vivo imaging of genes in pathological states, and may provide tools for the analysis of novel genes with functional genomics.     

Imaging gene expression in the brain with peptide nucleic acid (PNA) antisense radiopharmaceuticals and drug targeting technology

Antisense oligomers are potential pharmaceutical and radiopharmaceutical agents that can be used to modulate and image gene expression. Progress with in vivogene targeting using antisense-based therapeutics has been slower than expected during the last decade, owing to poor trans-cellular delivery of antisense agents. This chapter suggests that if antisense pharmacology is merged with drug targeting technology, then membrane barriers can be circumvented and antisense agents can be delivered to tissues in vivo. Without the application of drug targeting, the likelihood of success for an antisense drug development program is low, particularly for the brain which is protected by the blood-brain barrier (BBB). Among the different classes of antisense agents, peptide nucleic acids (PNA) present advantages for in vivoapplications over conventional and modified oligodeoxynucleotides (ODN), including phosphorothioates (PS)-ODN. Some advantages of PNAs include their electrically neutral backbone, low toxicity to neural cells, resistance to nucleases and peptidases, and lack of binding to plasma proteins. PNAs are poorly transported through cellular membranes, however, including the BBB and the brain cell membrane (BCM). Because the mRNA target for the antisense agent lies within the cytosol of the target cell, the BBB and the BCM must be circumvented in vivo, which ispossible with the use of chimeric peptide drug targeting technology. Chimeric peptides are formed by conjugation of a non-transportable drug, such as a PNA, to a drug delivery vector. The vector undergoes receptor-mediated transcytosis (RMT) through the BBB and receptor-mediated endocytosis through the BCM in vivo. When labeled with a radioisotope (e.g., ¹²⁵I or ¹¹¹In), the antisense chimeric peptide provides imaging of gene expressionin the brain in vivoin a sequence-specific manner. Further development of antisense radiopharmaceutical agents may allow for in vivoimaging of genes in pathological states, and may provide tools for the analysis of novel genes with functional genomics.     

Calcium Gluconate in Phosphate Buffered Saline Increases Gene Delivery with Adenovirus Type 5

Background

Adenoviruses are attractive vectors for gene therapy because of their stability in vivo and the possibility of production at high titers. Despite exciting preclinical data with various approaches, there are only a few examples of clear efficacy in clinical trials. Effective gene delivery to target cells remains the key variable determining efficacy and thus enhanced transduction methods are important.

Methods/Results

We found that heated serum could enhance adenovirus 5 mediated gene delivery up to twentyfold. A new protein-level interaction was found between fiber knob and serum transthyretin, but this was not responsible for the observed effect. Instead, we found that heating caused the calcium and phosphate present in the serum mix to precipitate, and this was responsible for enhanced gene delivery. This finding could have relevance for designing preclinical experiments with adenoviruses, since calcium and phosphate are present in many solutions. To translate this into an approach potentially testable in patients, we used calcium gluconate in phosphate buffered saline, both of which are clinically approved, to increase adenoviral gene transfer up to 300-fold in vitro. Gene transfer was increased with or without heating and in a manner independent from the coxsackie-adenovirus receptor. In vivo, in mouse studies, gene delivery was increased 2-, 110-, 12- and 13-fold to tumors, lungs, heart and liver and did not result in increased pro-inflammatory cytokine induction. Antitumor efficacy of a replication competent virus was also increased significantly.

Conclusion

In summary, adenoviral gene transfer and antitumor efficacy can be enhanced by calcium gluconate in phosphate buffered saline.     

Myeloid-Derived Suppressor Cells Regulate Natural Killer Cell Response to Adenovirus-Mediated Gene Transfer

The attendant innate and adaptive immune responses to viral vectors have posed a significant hurdle for clinical application of viral vector-mediated gene therapy. Previous studies have shown that natural killer (NK) cells play a critical role in innate immune elimination of adenoviral vectors in the liver. However, it is not clear how the NK cell response to adenoviral vectors is regulated. In this study, we identified a role for granulocytic myeloid-derived suppressor cells (G-MDSCs) in this process. We show that in vivo administration of adenoviral vectors results in rapid accumulation of G-MDSCs early during adenoviral infection. In vivo depletion of both MDSC populations, but not monocytic MDSCs (M-MDSCs) alone, resulted in accelerated clearance of adenoviral vectors in the liver. This was accompanied by enhanced NK cell proliferation and activation, suggesting a role for MDSCs, probably G-MDSCs, in suppressing NK cell activation and function in vivo. We further demonstrate in vitro that G-MDSCs, but not M-MDSCs, are responsible for the suppression of NK cell activation. In addition, we show that adenoviral infection activated G-MDSCs to produce higher levels of reactive oxygen species (ROS) and that G-MDSC-mediated suppression of NK cells is mediated by ROS, specifically, H₂O₂. This study demonstrates for the first time that the NK cell response to adenoviral vectors is negatively regulated by G-MDSCs and suggests that G-MDSC-based strategies could potentially improve the outcome of viral vector-mediated gene therapy.     

Inhibition of hepatitis B virus replication with linear DNA sequences expressing antiviral micro-RNA shuttles

RNA interference (RNAi) may be harnessed to inhibit viral gene expression and this approach is being developed to counter chronic infection with hepatitis B virus (HBV). Compared to synthetic RNAi activators, DNA expression cassettes that generate silencing sequences have advantages of sustained efficacy and ease of propagation in plasmid DNA (pDNA). However, the large size of pDNAs and inclusion of sequences conferring antibiotic resistance and immunostimulation limit delivery efficiency and safety. To develop use of alternative DNA templates that may be applied for therapeutic gene silencing, we assessed the usefulness of PCR-generated linear expression cassettes that produce anti-HBV micro-RNA (miR) shuttles. We found that silencing of HBV markers of replication was efficient (>75%) in cell culture and in vivo. miR shuttles were processed to form anti-HBV guide strands and there was no evidence of induction of the interferon response. Modification of terminal sequences to include flanking human adenoviral type-5 inverted terminal repeats was easily achieved and did not compromise silencing efficacy. These linear DNA sequences should have utility in the development of gene silencing applications where modifications of terminal elements with elimination of potentially harmful and non-essential sequences are required.     

Non-viral gene therapy for bone tissue engineering

The possibilities of using gene therapy for bone regeneration have been extensively investigated. Improvements in the design of new transfection agents, combining vectors and delivery/release systems to diminish cytotoxicity and increase transfection efficiencies have led to several successful in vitro, ex vivo and in vivo strategies. These include growth factor or short interfering ribonucleic acid (siRNA) delivery, or even enzyme replacement therapies, and have led to increased osteogenic differentiation and bone formation in vivo. These results provide optimism to consider use in humans with some of these gene-delivery strategies in the near future.     

Long-term enhancement of cytochrome P450 2B1/2 expression in rat hepatocyte spheroids through adenovirus-mediated gene transfer

Tissue-like structures of cells organized in vitrohave a great potential for a number of clinical and biomedical applications. Cell functions may be modulated with gene delivery, improving the characteristics of these structures. Hepatocytes that self-assemble into spheroids can be transduced through adenovirus-mediated gene transfer. An adenoviral vector (AdGFP) was employed to deliver a gene encoding for green fluorescent protein (GFP) in rat hepatocyte spheroids. GFP fluorescence was detected for at least one month. Furthermore, the rat cytochrome P450 2B1 gene (CYP2B1) was transferred through infection with a recombinant adenovirus (AdCYP2B1) in hepatocyte spheroids cultured in suspension. The CYP2B1/2 mRNA and apoprotein levels were continuously higher for over 23 days compared to phenobarbital-induced and control cultures. P450-catalyzed pentoxyresorufin-O-dealkylation activity was also high in the AdCYP2B1-infected spheroids. In these spheroid cultures, albumin and urea levels were similar to those in uninfected spheroid cultures, indicating that expression of the CYP2B1transgene did not impair these liver-specific functions. Hepatocyte spheroids transduced by recombinant adenoviral vectors can be efficiently used for drug metabolism studies, in implantation, and in bioartificial liver devices. This revised version was published online in August 2006 with corrections to the Cover Date.     

Construction of adenovirus for high level expression of small RNAs in mammalian cells

A series of plasmid vectors have been generated to allow the rapid construction of adenoviral vectors designed to express small RNA sequences. A truncated human U6 gene containing convenient restriction sites has been shown to be expressed at high levels following electroporation into a series of human cell lines. This gene was ligated into a promoterless adenoviral plasmid, and we have generated high titer virus by homologous recombination with adenoviral Addl327 DNA in 293 cells. Recombinant adenovirus containing a hammerhead ribozyme sequence targeted toward the Bcl-2 mRNA has been used to transduce a panel of human tumor cell lines. We have demonstrated high level expression of the recombinant U6 gene containing the ribozyme and reduction of Bcl-2 protein in transduced cells. These plasmids are suitable for the development of adenoviral vectors designed to express both ribozymes and antisense RNA in human cells.     

A Novel Micro-Linear Vector for In Vitro and In Vivo Gene Delivery and Its Application for EBV Positive Tumors

Background

The gene delivery vector for DNA-based therapy should ensure its transfection efficiency and safety for clinical application. The Micro-Linear vector (MiLV) was developed to improve the limitations of traditional vectors such as viral vectors and plasmids.

Methods

The MiLV which contained only the gene expression cassette was amplified by polymerase chain reaction (PCR). Its cytotoxicity, transfection efficiency in vitro and in vivo, duration of expression, pro-inflammatory responses and potential application for Epstein-Barr virus (EBV) positive tumors were evaluated.

Results

Transfection efficiency for exogenous genes transferred by MiLV was at least comparable with or even greater than their corresponding plasmids in eukaryotic cell lines. MiLV elevated the expression and prolonged the duration of genes in vitro and in vivo when compared with that of the plasmid. The in vivo pro-inflammatory response of MiLV group was lower than that of the plasmid group. The MEKK1 gene transferred by MiLV significantly elevated the sensitivity of B95-8 cells and transplanted tumor to the treatment of Ganciclovir (GCV) and sodium butyrate (NaB).

Conclusions

The present study provides a safer, more efficient and stable MiLV gene delivery vector than plasmid. These advantages encourage further development and the preferential use of this novel vector type for clinical gene therapy studies.     

Viral Vectors for Gene Delivery and Expression in the CNS

Viral vectors have emerged as an important tool for manipulating gene expression in the adult mammalian brain. The adult brain is composed largely of nondividing cells, and therefore DNA viruses have become the vehicle of choice for neurobiologists interested in somatic gene transfer. Recombinant viral vectors based upon adenovirus or herpes simplex virus have been created in which a gene essential for viral replication is removed and a gene of interest is inserted in the viral genome. While this eliminates pathogenicity due to viral replication, retention of viral genes and continued expression of these genes may limit the potential of the current generation of vectors. Defective viral vectors represent a different approach, in which only viral recognition signals are used to allow packaging of foreign DNA into a viral coat while eliminating the possibility of viral gene expression within target cells. The defective HSV vector has been used to transfer genes into the adult rat brain. This vector has also been used for analysis of the preproenkephalin promoterin vivo,and important regions of this promoter have been identified using this technique. A modification ofin situPCR has been developed as an adjunctive tool for sensitively documenting the presence of vector DNA within target cells duringin vivopromoter studies. Finally, the adenoassociated virus vector has been used as the first fully defective DNA viral vector, which also eliminates any contamination by helper viruses. This vector can transfer genes into the mammalian brain and has shown significant behavioral recovery in a rodent model of Parkinson's disease. Future work will undoubtedly result in still more diverse and improved vectors; however, these studies have documented the importance of viral vectors to both basic neurobiology and the potential treatment of neurologic disease.     

An EBV‐based plasmid can replicate and maintain in stem cells

Viral vectors have a wide range of applications in biology, particularly in gene therapy. Based on their integration capacity, viral vectors are classified as either integrating or non‐integrating vectors. Although integrating vectors, such as lentivectors, have the ability to direct prolonged expression of exogenous genes, manipulation of the host genome is an inappropriate feature of these gene delivery tools. Non‐integrating vectors, such as episomal replicating plasmids, can replicate and persist in host cells for long periods without any chromosomal interruption. These advantages made them good tools for gene induction purposes in gene therapy and basic studies. Due to the necessity of gene induction in stem cells for study of mammalian development and targeted differentiation, the use of integrating vectors for prolonged expression of genes of interest has been developed. Application of replicating plasmids can overcome some drawbacks associated with integrating vectors, although replication and maintenance of these plasmids can differ between cell types. Previously, it has been shown that such plasmids can be maintained in human embryonic stem cells for more than one month, but the rate of the plasmid replication during the host cell cycle has not been elucidated. In the present study, we showed that an EBV‐based plasmid can replicate simultaneously with host in pluripotent and multipotent human and mouse stem cells and can be sustained for long time periods in dividing cells. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:1579–1585, 2015     

Adenoviral vectors for gene transfer and therapy

Due to the very efficient nuclear entry mechanism of adenovirus and its low pathogenicity for humans, adenovirus-based vectors have become gene delivery vehicles that are widely used for transduction of different cell types, especially for quiescent, differentiated cells, in basic research, in gene therapy applications, and in vaccine development. As an important basis for their use as gene medicine, adenoviral vectors can be produced in high titers, they can transduce cells in vivo with transgenes of more than 30 kb, and they do not integrate into the host cell genome. Recent advances in the development of adenoviral vectors have brought considerable progress on issues like target cell specificity and tropism modification, long-term expression of the transgene, as well as immunogenicity and toxicity in vivo, and have suggested that the different generations of non-replicative and replicative vectors available today will each suit best for certain applications.     

Adenoviral Vectors Stimulate Glucagon Transcription in Human Mesenchymal Stem Cells Expressing Pancreatic Transcription Factors

Viral gene carriers are being widely used as gene transfer systems in (trans)differentiation and reprogramming strategies. Forced expression of key regulators of pancreatic differentiation in stem cells, liver cells, pancreatic duct cells, or cells from the exocrine pancreas, can lead to the initiation of endocrine pancreatic differentiation. While several viral vector systems have been employed in such studies, the results reported with adenovirus vectors have been the most promising in vitro and in vivo. In this study, we examined whether the viral vector system itself could impact the differentiation capacity of human bone-marrow derived mesenchymal stem cells (hMSCs) toward the endocrine lineage. Lentivirus-mediated expression of Pdx-1, Ngn-3, and Maf-A alone or in combination does not lead to robust expression of any of the endocrine hormones (i.e. insulin, glucagon and somatostatin) in hMSCs. Remarkably, subsequent transduction of these genetically modified cells with an irrelevant early region 1 (E1)-deleted adenoviral vector potentiates the differentiation stimulus and promotes glucagon gene expression in hMSCs by affecting the chromatin structure. This adenovirus stimulation was observed upon infection with an E1-deleted adenovirus vector, but not after exposure to helper-dependent adenovirus vectors, pointing at the involvement of genes retained in the E1-deleted adenovirus vector in this phenomenon. Lentivirus mediated expression of the adenovirus E4-ORF3 mimics the adenovirus effect. From these data we conclude that E1-deleted adenoviral vectors are not inert gene-transfer vectors and contribute to the modulation of the cellular differentiation pathways.