High-efficiency transduction and long-term gene expression with a murine stem cell retroviral vector encoding the green fluorescent protein in human marrow stromal cells.

Bone marrow stromal cells (MSCs) are unique mesenchymal cells that have been utilized as vehicles for the delivery of therapeutic proteins in gene therapy protocols. However, there are several unresolved issues regarding their potential therapeutic applications. These include low transduction efficiency, attenuation of transgene expression, and the technical problems associated with drug-based selection markers. To address these issues, we have developed a transduction protocol that yields high-level gene transfer into human MSCs, employing a murine stem cell virus-based bicistronic vector containing the green fluorescent protein (GFP) gene as a selectable marker. Transduction of MSCs plated at low density for 6 hr per day for 3 days with high-titer viral supernatant resulted in a gene transfer efficiency of 80+/-6% (n = 10) as measured by GFP fluorescence. Neither centrifugation nor phosphate depletion increased transduction efficiency. Assessment of amphotropic receptor (Pit-2) expression by RT-PCR demonstrated that all MSCs expressing the receptor were successfully transduced. Cell cycle distribution profiles measured by propidium iodide staining showed no correlation with the susceptibility of MSCs to transduction by the retroviral vector. Human MSCs sequentially transduced with an adenoviral vector encoding the ecotropic receptor and ecotropic retroviral vector encoding GFP demonstrated that all MSCs are susceptible to retroviral transduction. We further showed that both genes of bicistronic vector are expressed for at least 6 months in vitro and that transgene expression did not affect the growth or osteogenic differentiation potential of MSCs. Future studies will be directed toward the development of gene therapy protocols employing this strategy.

High-level globin gene expression mediated by a recombinant adeno-associated virus genome that contains the 3' gamma globin gene regulatory element and integrates as tandem copies in erythroid cells.

Recombinant adeno-associated virus (rAAV) vectors are being evaluated for gene therapy applications. Using purified rAAV containing a mutationally marked globin gene (A(gamma)*) and sites 2, 3, and 4 from the locus control region (rHS432A(gamma)*), but lacking a drug-resistance gene, we investigated the relationship between multiplicity of infection (MOI), gene expression, and unselected genome integration in erythroid cells. Most primary erythroid progenitors were transduced as reflected by A(gamma)* mRNA in mature colonies but only at an MOI of greater than 5 x 10(7). Using immortalized erythroleukemia cells as a model, we found that fewer than one half of the colonies that contained the A(gamma)* transcript had an integrated, intact rHS432A(gamma)* genome. rHS432A(gamma)* integrated as a single copy with expression at approximately 50% the level of an endogenous gamma globin gene. A second vector, rHS32A(gamma)*3'RE, containing the regulatory element (RE) from 3' to the chromosomal A(gamma) globin gene, integrated as an intact, tandem head to tail concatamer with a median copy number of 6 with variable expression per copy ranging from approximately onefold to threefold that of an endogenous y globin gene. These results establish that purified rAAV can be used to achieve integration and functional expression of a globin gene in erythroid cells, but only when high MOIs are used.