Human and mouse embryonic stem (ES) cells have the capacity to differentiate into derivatives of all three germ layers, suggesting novel therapies for degenerative, metabolic, and traumatic disorders. ES-based regenerative medicine will be further advanced by the development of reliable methods for transgene introduction and expression. Here, we show infection of human and mouse embryonic stem (ES) cells with two of the most popular vectors in gene transfer, adenovirus type 5 (Ad5) and adeno-associated virus (AAV; serotypes 2, 4, and 5). All vectors express the nuclear-localized marker gene beta-galactosidase expressed from the Rous Sarcoma Virus long terminal repeat (RSV-LTR). Both Ad5 and AAV2 infected human and mouse ES cells and gave rise to beta-galactosidase expression. AAV4 and 5 did not yield detectable levels of beta-galactosidase expression. Quantitative PCR analysis of virally infected human and mouse ES cells revealed that only Ad5 and AAV2 are capable of transducing both cell-types. No viral DNA was detected in cells infected with either AAV4 or AAV5. Infection and subsequent differentiation of mouse and human ES cells with Ad5 showed that beta-galactosidase-expressing cells were restricted to cells in the interior of the embryoid body mass. No beta-galactosidase expression was observed in AAV-infected cells following differentiation. There was no difference in morphology or differentiation patterns between infected and noninfected differentiating mouse and human ES cells. Differentiation of hES cells prior to infection led to transduction of neuronally differentiated cells with good efficiency using all vectors. These data show that Ad5- and AAV2-based vectors are capable of infecting both human and mouse ES cells, in both their undifferentiated and differentiated states, whereas AAV4 and AAV5 can infect human and mouse ES cells only following differentiation.
Gene therapy using Fas ligand (FasL) for treatment of tumours and protection of transplant rejection is hampered because of the systemic toxicity of FasL. In the present study, recombinant replication-defective adenovirus vectors (RAds) encoding FasL under the control of either the neuronal-specific neuronal-specific enolase (NSE) promoter or the astrocyte-specific glial fibrillary acidic protein (GFAP) promoter have been constructed. The cell type-specific expression of FasL in both neurons and glial cells in primary cultures, and in neuronal and glial cell lines is demonstrated. Furthermore, transgene expression driven by the neuronal and glial promoter was not detected in fibroblastic or epithelial cell lines. Expression of FasL driven by a major immediate early human cytomegalovirus promoter (MIEhCMV) was, however, achieved in all cells tested. As a final test of the stringency of transgene-specific expression, the RAds were injected directly into the bloodstream of mice. The RAds encoding FasL under the control of the non-cell type-specific MIEhCMV promoter induced acute generalized liver haemorrhage with hepatocyte apoptosis, while the RAds containing the NSE or GFAP promoter sequences were completely non-toxic. This demonstrates the specificity of transgene expression, enhanced safety during systemic administration, and tightly regulated control of transgene expression of highly cytotoxic gene products, encoded within transcriptionally targeted RAds.
To achieve transient transgenesis within specific areas or cell populations in the adult central nervous system (CNS), we have developed a dual adenoviral vector system encoding for cell-type-specific and regulatable transcription units. To achieve combined cell-type-specific transcriptional targeting and inducible expression, we have engineered the expression of the tetracycline-dependent transcriptional elements (1) to be under the transcriptional control of either the astrocyte-specific, glial fibrillary acidic protein (GFAP) (2) or the neuronal specific enolase (NSE) promoter (3) within a dual adenoviral vector system. Cell-type specificity, inducibility, and levels of transgene expression were characterized in vitro in cell lines, and primary neocortical cultures and in the central nervous system (CNS) in vivo, and compared to a powerful pancellular beta-actin/CMV promoter. We demonstrate that the GFAP promoter is able to restrict tetracycline-dependent transgene expression to glial cells in cell lines, primary cultures, and in the CNS in vivo. However, although the NSE promoter did not show neuronal restricted transgene expression in vitro, it did so in the CNS in vivo. Our dual viral system also has provided evidence that an excess of transactivator is needed to achieve maximal transgene expression. Administration of doxycycline completely abrogated transgene expression both in vitro and in vivo. Consequently, our strategy demonstrates that combined cell-type specificity and simultaneous regulation of transgene expression can be obtained in the brain using adenoviral vectors.
Gene transfer using recombinant adeno-associated virus (rAAV) vectors shows great promise for human gene therapy. The broad host range, low level of immune response, and longevity of gene expression observed with these vectors in numerous disease paradigms has enabled the initiation of a number of clinical trials using this gene delivery system. This review presents an overview of the current developments in the field of AAV-mediated gene delivery. Such developments include the establishment of new production methods allowing the generation of high titer preparations, improved purification methods, the use of alternative AAV serotypes, and the generation of trans-splicing rAAV genomes. Together, these developments have improved results interpretation, host range, and the coding capacity of rAAV vectors. Furthermore, the recent identification of regions within the viral capsid that are amenable to modification has begun to address the issue of direct rAAV vector targeting, which could potentially allow targeted gene delivery to specific cell populations. The versatility shown by this vector has enabled new diseases to be realistically considered for therapeutic intervention and considerably broadened the scope of gene therapy.
To further develop our understanding of anterior pituitary (AP) function and to aid the development of gene therapy strategies for the treatment of pituitary diseases, adenovirus (Ad)-mediated gene transfer to the AP gland will be a useful tool. Although successful widespread gene transfer within the AP has been achieved using first generation Ads the ability to control transgene expression would be very beneficial when studying AP regulatory functions and delivering a potentially therapeutic gene into the AP gland. A dual adenoviral vector system encoding for cell type-specific and regulatable transcription units was developed to achieve transcriptionally targeted transgenesis within specific cell populations in the adult AP gland. To achieve regulatable transgene expression within predetermined AP cells, the tetracycline-responsive transcriptional elements have been engineered to be under the control of human, lactotroph-specific PRL (hPRL) promoter elements within a dual adenoviral vector system. The inducibility, cell type specificity, and levels of transgene expression were characterized in vitro and in vivo and compared with the strong ubiquitous beta-actin/human cytomegalovirus (CAG) promoter. Inducible expression of the marker gene beta-galactosidase under the control of the hPRL promoter was restricted to lactotrophic tumor cell lines and lactotrophic cells within primary AP cultures. Lactotroph cell type specificity and inducible transgene expression were also observed within the AP gland in vivo, and this could be switched on or off. Administration of doxycycline abrogated transgene expression both in vitro and in vivo. Our results also provide evidence that an excess of trans-activator is needed to achieve maximal transgene expression. Our data indicate that combined transcriptional and inducible transgenesis can be achieved using adenoviral vectors that allow spatial and temporal restriction of transgene expression within the adult AP gland in vivo.
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