Optimizing Transgene Configuration and Protein Fusions to Maximize Dopamine Production for the Gene Therapy of Parkinson's Disease.

Pharmacological dopamine replacement therapies provide the most well-established treatments for Parkinson's disease (PD). However, these long-term treatments can lead to motor complications and off-target effects. ProSavin(®), a lentiviral vector (LV)-based gene therapy approach aimed at restoring local and continuous dopamine production, through delivery of three enzymes in the dopamine biosynthesis pathway, was demonstrated to be safe and well-tolerated in a phase I/II clinical study of patients with advanced PD. Although improvements in motor behaviour were observed, the data indicated that higher levels of dopamine replacement might be required to maximize benefit. We attempted to increase production of dopamine, and its precursor L-Dopa in LV-transduced cells, by optimizing the gene order in the ProSavin expression cassette, and by creating fusions of two or three of the transgenes, using linker sequences. In vitro analysis showed that several gene arrangements provided significantly increased dopamine and/or L-Dopa production compared with ProSavin, and that LV titers and transgene expression were not affected by introducing gene fusions. One vector, equine infectious anemia virus (EIAV)-TCiA, was selected for further characterization and showed significant improvements in dopamine and L-Dopa production compared with ProSavin, in human neuronal cells. Further characterization of EIAV-TCiA demonstrated expression of all three dopamine enzymes in vivo and faithful delivery and integration of the expected gene expression cassette within the genome of target cells, as assessed by Northern and Southern blotting. In conclusion, we have developed a novel LV vector with an increased capacity for L-Dopa and dopamine production compared with the current ProSavin vector. Clinical evaluation of this vector will be performed to assess the benefits in patients with PD.

Assessment of Integration-defective HIV-1 and EIAV Vectors In Vitro and In Vivo.

The interest in integrase-defective lentiviral vectors (IDLVs) stems from their potential advantage of large cloning capacity and broad cell tropism while avoiding the possibility of insertional mutagenesis. Here, we directly compared the transducing potential of IDLVs based on the equine infectious anemia virus (EIAV) to the more commonly described HIV-1 IDLVs. IDLVs were constructed by introducing equivalent single/triple mutations into the integrase catalytic triad. We show that both the single and the triple mutant HIV-1 IDLVs transduce the PC12 cells, but not the C2C12 cells, with similar efficiency to their parental HIV-1 vector. In contrast, the single and triple EIAV IDLVs did not efficiently transduce either differentiated cell line. Moreover, this HIV-1 IDLV-mediated expression was independent of any residual integration activity because reporter expression was lost when cell cycling was restored. Four weeks following stereotactic administration into adult rat brains, only the single HIV-1 IDLV mutant displayed a comparable transduction profile to the parental HIV-1 vector. In contrast, neither EIAV IDLV mutants showed significant reporter gene expression. This work indicates that the transducing potential of IDLVs appears to depend not only on the choice of integrase mutation and type of target cell, but also on the nature of the lentiviral vector.Molecular Therapy - Nucleic Acids (2012) 1, e60; doi:10.1038/mtna.2012.53; published online 11 December 2012.

A stable producer cell line for the manufacture of a lentiviral vector for gene therapy of Parkinson's disease.

ProSavin is an equine infectious anemia virus vector-based gene therapy for Parkinson's disease for which inducible HEK293T-based producer cell lines (PCLs) have been developed. These cell lines demonstrate stringent tetracycline-regulated expression of the packaging components and yield titers comparable to the established transient production system. A prerequisite for the use of PCL-derived lentiviral vectors (LVs) in clinical applications is the thorough characterization of both the LV and respective PCL with regard to identity and genetic stability. We describe the detailed characterization of two ProSavin PCLs (PS5.8 and PS46.2) and resultant ProSavin vector. The two cell lines demonstrate stable production of vector over a time period sufficient to allow generation of master and working cell banks, and subsequent large-scale vector production. ProSavin generated from the PCLs performs comparably in vivo to that produced by the standard transient transfection process with respect to transduction efficiency and immunogenicity. The development of ProSavin PCLs, and the detailed characterization described here, will aid the advancement of ProSavin for clinical application.