Designer Gene Delivery Vectors: Molecular Engineering and Evolution of Adeno-Associated Viral Vectors for Enhanced Gene Transfer

Gene delivery vectors based on adeno-associated virus (AAV) are highly promising due to several desirable features of this parent virus, including a lack of pathogenicity, efficient infection of dividing and non-dividing cells, and sustained maintenance of the viral genome. However, several problems should be addressed to enhance the utility of AAV vectors, particularly those based on AAV2, the best characterized AAV serotype. First, altering viral tropism would be advantageous for broadening its utility in various tissue or cell types. In response to this need, vector pseudotyping, mosaic capsids, and targeting ligand insertion into the capsid have shown promise for altering AAV specificity. In addition, library selection and directed evolution have recently emerged as promising approaches to modulate AAV tropism despite limited knowledge of viral structure–function relationships. Second, pre-existing immunity to AAV must be addressed for successful clinical application of AAV vectors. “Shielding” polymers, site-directed mutagenesis, and alternative AAV serotypes have shown success in avoiding immune neutralization. Furthermore, directed evolution of the AAV capsid is a high throughput approach that has yielded vectors with substantial resistance to neutralizing antibodies. Molecular engineering and directed evolution of AAV vectors therefore offer promise for generating ‘designer’ gene delivery vectors with enhanced properties

Transduction of Brain Dopamine Neurons by Adenoviral Vectors Is Modulated by CAR Expression: Rationale for Tropism Modified Vectors in PD Gene Therapy

Gene-based therapy is a new paradigm for the treatment of Parkinson disease (PD) and offers considerable promise for precise targeting and flexibility to impact multiple pathobiological processes for which small molecule agents are not available. Some success has been achieved utilizing adeno-associated virus for this approach, but it is likely that the characteristics of this vector system will ultimately create barriers to progress in clinical therapy. Adenovirus (Ad) vector overcomes limitations in payload size and targeting. The cellular tropism of Ad serotype 5 (Ad5)-based vectors is regulated by the Ad attachment protein binding to its primary cellular receptor, the coxsackie and adenovirus receptor (CAR). Many clinically relevant tissues are refractory to Ad5 infection due to negligible CAR levels but can be targeted by tropism-modified, CAR-independent forms of Ad. Our objective was to evaluate the role of CAR protein in transduction of dopamine (DA) neurons in vivo.Ad5 was delivered to the substantia nigra (SN) in wild type (wt) and CAR transgenic animals. Cellular tropism was assessed by immunohistochemistry (IHC) in the SN and striatal terminals. CAR expression was assessed by western blot and IHC. We found in wt animals, Ad5 results in robust transgene expression in astrocytes and other non-neuronal cells but poor infection of DA neurons. In contrast, in transgenic animals, Ad5 infects SNc neurons resulting in expression of transduced protein in their striatal terminals. Western blot showed low CAR expression in the ventral midbrain of wt animals compared to transgenic animals. Interestingly, hCAR protein localizes with markers of post-synaptic structures, suggesting synapses are the point of entry into dopaminergic neurons in transgenic animals.These findings demonstrate that CAR deficiency limits infection of wild type DA neurons by Ad5 and provide a rationale for the development of tropism-modified, CAR-independent Ad-vectors for use in gene therapy of human PD

Gene therapy strategies for intracranial tumours: glioma and pituitary adenomas

Intracranial tumours such as brain gliomas and pituitary adenomas pose a challenging area of research for the development of gene therapy strategies, both from the point of view of the severity of the diseases, to the physiological implication of gene delivery into the central nervous system and pituitary gland. On the one hand, brain gliomas are very malignant tumours, with a life expectancy of six months to a year at the most after the time of diagnosis, in spite of advances in treatment modalities which involve chemotherapy, surgery and radiotherapy. Gene therapy for these tumours is therefore a very attractive therapeutic modality which due to the severity of the disease is already in clinical trials. On the other hand, pituitary tumours are usually benign, and in most cases, treatment is successful. Nevertheless, there are some instances, especially with the macroadenomas and some invasive tumours in which treatment fails. Gene therapy strategies for these adenomas therefore needs to progress substantially in terms of safety, adverse side effects and physiological impact on the normal pituitary gland before clinical implementation.In this paper, we will review gene delivery systems both viral and non-viral and several therapeutic strategies which could be implemented for the treatment of these diseases. These include cytotoxic approaches both conditional and direct, immune-stimulatory strategies, anti-angiogenic strategies and approaches which harness pro-apoptotic and tumour suppressor gene targets. We will also review the models which are currently available in which these gene therapy strategies can be tested experimentally.This new therapeutic modality holds enormous promise, but we still need substantial improvements both from the delivery, efficacy and safety stand points before it can become a clinical reality

Gene therapy strategies for intracranial tumours, glioma and pituitary adenomas

Intracranial tumours such as brain gliomas and pituitary adenomas pose a challenging area of research for the development of gene therapy strategies, both from the point of view of the severity of the diseases, to the physiological implication of gene delivery into the central nervous system and pituitary gland. On the one hand, brain gliomas are very malignant tumours, with a life expectancy of six months to a year at the most after the time of diagnosis, in spite of advances in treatment modalities which involve chemotherapy, surgery and radiotherapy. Gene therapy for these tumours is therefore a very attractive therapeutic modality which due to the severity of the disease is already in clinical trials. On the other hand, pituitary tumours are usually benign, and in most cases, treatment is successful. Nevertheless, there are some instances, especially with the macroadenomas and some invasive tumours in which treatment fails. Gene therapy strategies for these adenomas therefore needs to progress substantially in terms of safety, adverse side effects and physiological impact on the normal pituitary gland before clinical implementation. In this paper, we will review gene delivery systems both viral and non-viral and several therapeutic strategies which could be implemented for the treatment of these diseases. These include cytotoxic approaches both conditional and direct, immune-stimulatory strategies, anti-angiogenic strategies and approaches which harness pro-apoptotic and tumour suppressor gene targets. We will also review the models which are currently available in which these gene therapy strategies can be tested experimentally. This new therapeutic modality holds enormous promise, but we still need substantial improvements both from the delivery, efficacy and safety stand points before it can become a clinical reality