Long-term AAV vector gene and protein expression in mouse brain from a small pan-cellular promoter is similar to neural cell promoters.

The neurogenetic, lysosomal enzyme (LSE) deficiency diseases are characterized by storage lesions throughout the brain; therefore, gene transfer needs to provide widespread distribution of the normal enzyme. Adeno-associated virus (AAV) vectors can be effective in the brain despite limited transduction because LSEs are exported to neighboring cells (cross-correction) to reverse the metabolic deficit. The extent of correction is determined by a combination of the total amount of LSE produced by a vector and the spatial distribution of the vector within the brain. Neuron-specific promoters have been used in the brain because AAV predominantly transduces neurons. However, these promoters are large, using up a substantial amount of the limited cloning capacity of AAV vector genomes. A small promoter that is active in all cells, from the LSE beta-glucuronidase (GUSB), has been used for long-term expression in AAV vectors in the brain but the natural promoter is expressed at very low levels. The amount of LSE exported from a cell is proportional to the level of transcription, thus more active promoters would export more LSE for cross-correction, but direct comparisons have not been reported. In this study, we show that in long-term experiments (>6 months) the GUSB minimal promoter (hGBp) expresses the hGUSB enzyme in brain at similar levels as the neuron-specific enolase promoter or the promoter from the latency-associated transcript of herpes simplex virus. The hGBp minimal promoter thus may be useful for long-term expression in the central nervous system of large cDNAs, bicitronic transcription units, self-complimentary or other designs with size constraints in the AAV vector system.

Modification of multiple transcriptional regulatory elements in a Moloney murine leukemia virus gene transfer vector circumvents silencing in fibroblast grafts and increases levels of expression of the transferred enzyme.

Down-regulation of retroviral vector expression occurs in a number of cell types after transplantation. Although a number of vector elements have been shown to affect expression in specific experimental situations, the results can vary depending on the specific cDNA being expressed, the individual retroviral elements included in vectors, the promoter, or the inclusion of selectable markers. In previous experiments with the lysosomal enzyme beta-glucuronidase, silencing has occurred in more than 95% of transduced cells regardless of the position of the expression unit within the vector, whether a eukaryotic or viral promoter was used, whether a bacterial selectable marker gene was present or not, the target cell type, or the species of the host. It has been a consistent finding that a small number of continuously expressing cells persist for long periods after transplantation. In this study we found that deletion of all the transcriptional regulatory elements from the vector LTR, inclusion of a permissive primer binding site sequence, and use of a eukaryotic housekeeping promoter could greatly increase the number of expressing cells in fibroblast grafts in subcutaneous neo-organs and in the brain. Furthermore, the level of enzyme expression was increased five-fold on a per positive cell basis, indicating that the deleted regulatory elements were exerting a negative effect on expression in the few cells that were positive before modification of the vector. This resulted in more than a 50-fold increase in total activity compared with the previous highest expressing vector.

Gene transfer of low levels of beta-glucuronidase corrects hepatic lysosomal storage in a large animal model of mucopolysaccharidosis VII.

Gene therapy has been at least partially effective in several mouse disease models, but treatment of large mammals has been more difficult to achieve. One major limitation is that only low levels of expression of the corrective gene are often maintained in vivo. In a mouse model of the lysosomal storage disease mucopolysaccharidosis (MPS) type VII (Sly disease) with a null mutation in beta-glucuronidase, gene transfer experiments have shown that only 1-2% of normal beta-glucuronidase can correct the storage in some major organs. In contrast, MPS VII dogs, cats, and humans that have residual beta-glucuronidase activity levels in this range are affected. Thus, higher levels of transferred gene expression may be needed to achieve a therapeutic effect in large animals and humans. We tested this by examining liver pathology in MPS VII dogs after intraperitoneal transplantation of neo-organs containing retrovirus vector-corrected autologous fibroblasts that expressed low levels of beta-glucuronidase. The enzyme secreted from the neo-organs was taken up by the liver and significantly reduced the substrate content compared with untreated dogs. This suggests that small amounts of normal enzyme, when delivered to target tissues, may be therapeutically effective in human MPS VII patients.

Single cell analysis and selection of living retrovirus vector-corrected mucopolysaccharidosis VII cells using a fluorescence-activated cell sorting-based assay for mammalian beta-glucuronidase enzymatic activity.

Mutations in the acid beta-glucuronidase gene lead to systemic accumulation of undegraded glycosaminoglycans in lysosomes and ultimately to clinical manifestations of mucopolysaccharidosis VII (Sly disease). Gene transfer by retrovirus vectors into murine mucopolysaccharidosis VII hematopoietic stem cells or fibroblasts ameliorates glycosaminoglycan accumulation in some affected tissues. The efficacy of gene therapy for mucopolysaccharidosis VII depends on the levels of beta-glucuronidase secreted by gene-corrected cells; therefore, enrichment of transduced cells expressing high levels of enzyme prior to transplantation is desirable. We describe the development of a fluorescence-activated cell sorter-based assay for the quantitative analysis of beta-glucuronidase activity in viable cells. Murine mucopolysaccharidosis VII cells transduced with a beta-glucuronidase retroviral vector can be isolated by cell sorting on the basis of beta-glucuronidase activity and cultured for further use. In vitro analysis revealed that sorted cells have elevated levels of beta-glucuronidase activity and secrete higher levels of cross-correcting enzyme than the population from which they were sorted. Transduced fibroblasts stably expressing beta-glucuronidase after subcutaneous passage in the mucopolysaccharidosis VII mouse can be isolated by cell sorting and expanded ex vivo. A relatively high percentage of these cells maintain stable expression after secondary transplantation, yielding significantly higher levels of enzymatic activity than that generated in the primary transplant.

Sustained production of beta-glucuronidase from localized sites after AAV vector gene transfer results in widespread distribution of enzyme and reversal of lysosomal storage lesions in a large volume of brain in mucopolysaccharidosis VII mice.

The lysosomal storage disorders are a large group of inherited diseases that involve central nervous system degeneration. The disease in the brain has generally been refractory to treatment, which will require long-term correction of lesions dispersed throughout the central nervous system to be effective. A promising approach is somatic gene therapy but the methods have so far been inadequate because they have only achieved short-term or localized improvements. A potential approach to overcome these limitations is to obtain sustained high level expression and secretion of the missing normal enzyme from a small group of cells for export to neighboring diseased cells, which might allow the therapeutic protein to reach distal sites. We tested this in a mouse model of mucopolysaccharidosis VII (Sly disease) using an adeno-associated virus vector. After a single treatment the vector continuously produced the normal enzyme from infected cells at the injection sites. The secreted enzyme was disseminated along most of the neuraxis, resulting in widespread reversal of the hallmark pathology. An extensive sphere of correction surrounding the transduction sites was created, suggesting that a limited number of appropriately spaced sites of gene transfer may provide overlapping spheres of enzyme diffusion to cover a large volume of brain tissue.

Production of increased titer retrovirus vectors from stable producer cell lines by superinfection and concentration.

Retrovirus vector titers could be increased by more than 50-fold after multiple superinfections of packaging cells with vector virus expressing a complementing host-range envelope glycoprotein. The high level of expression was stable for at least 90 passages in culture. The optimum conditions for density of cell seeding, length of incubation, and temporary storage of virus-containing medium was determined. This vector preparation was further concentrated by 20-fold or more in commercially available ultrafilters, which can be used with standard laboratory centrifuges. Ultrafilters from three different manufactures, with molecular weight cutoffs of 30-1000 kiloDaltons, were tested for concentrating ability and for toxicity of the concentrate on target cells. These methods can be used to produce vector virus containing retrovirus envelope proteins in milliliter volumes at titers in excess of 10(8) c.f.u./ml and in liter volumes at greater than 10(6) c.f.u./ml.

High level expression and export of beta-glucuronidase from murine mucopolysaccharidosis VII cells corrected by a double-copy retrovirus vector.

Retrovirus vectors were constructed to transfer and express the cDNA of the human lysosomal acid hydrolase beta-glucuronidase (GUSB) under control of the human GUSB promoter. Expression of the transcription unit (minigene) was evaluated in a GUSB-negative cell line established from a mouse with the lysosomal storage disease mucopolysaccharidosis (MPS) type VII. A vector designed to transfer single copies of the minigene (N2H beta H) expressed normal levels of GUSB activity in the deficient cells. GUSB expression was increased to several times greater than normal by inserting the minigene into a double-copy vector (DCH beta H), which places one copy of the transcription unit upstream of the retrovirus promoter in both the 3' and 5' long terminal repeats (LTRs) of the integrated provirus. The specific activity of GUSB and a control normal lysosomal enzyme, alpha-galactosidase (GLA), were higher in normal and in vector-corrected cells from confluent cultures than in subconfluent dividing cells. The ratios of GUSB to GLA were similar at all phases of cell growth, but the level of GUSB expression from the double copy vector was several-fold higher than from the single copy vector. To determine if this effect was controlled by the GUSB promoter, a vector was constructed using the thymidine kinase (TK) promoter to drive the human GUSB cDNA (NTK beta H). The levels of GUSB in cells corrected with this vector exhibited the same cell density dependent pattern as when the GUSB promoter was used, indicating that the variation in enzymatic activity was not a function of the GUSB promoter.(ABSTRACT TRUNCATED AT 250 WORDS)