Substitution of blood coagulation factor X-binding to Ad5 by position-specific PEGylation: Preventing vector clearance and preserving infectivity.

The biodistribution of adenovirus type 5 (Ad5) vector particles is heavily influenced by interaction of the particles with plasma proteins, including coagulation factor X (FX), which binds specifically to the major Ad5 capsid protein hexon. FX mediates hepatocyte transduction by intravenously-injected Ad5 vectors and shields vector particles from neutralization by natural antibodies and complement. In mice, mutant Ad5 vectors that are ablated for FX-binding become detargeted from hepatocytes, which is desirable for certain applications, but unfortunately such FX-nonbinding vectors also become sensitive to neutralization by mouse plasma proteins. To improve the properties of Ad5 vectors for systemic delivery, we developed a strategy to replace the natural FX shield by a site-specific chemical polyethylene glycol shield. Coupling of polyethylene glycol to a specific site in hexon hypervariable region 1 yielded vector particles that were protected from neutralization by natural antibodies and complement although they were unable to bind FX. These vector particles evaded macrophages in vitro and showed significantly improved pharmacokinetics and hepatocyte transduction in vivo. Thus, site-specific shielding of Ad5 vectors with polyethylene glycol rendered vectors FX-independent and greatly improved their properties for systemic gene therapy.

An ex vivo loop system models the toxicity and efficacy of PEGylated and unmodified adenovirus serotype 5 in whole human blood.

Polyethylene glycol coating (PEGylation) of adenovirus serotype 5 (Ad5) has been shown to effectively reduce immunogenicity and increase circulation time of intravenously administered virus in mouse models. Herein, we monitored clot formation, complement activation, cytokine release and blood cell association upon addition of uncoated or PEGylated Ad5 to human whole blood. We used a novel blood loop model where human blood from healthy donors was mixed with virus and incubated in heparin-coated PVC tubing while rotating at 37 degrees C for up to 8 h. Production of the complement components C3a and C5a and the cytokines IL-8, RANTES and MCP-1 was significantly lower with 20K-PEGylated Ad5 than with uncoated Ad5. PEGylation prevented clotting and reduced Ad5 binding to blood cells in blood with low ability to neutralize Ad5. The effect was particularly pronounced in monocytes, granulocytes, B-cells and T-cells, but could also be observed in erythrocytes and platelets. In conclusion, PEGylation of Ad5 can reduce the immune response mounted in human blood, although the protective effects are rather modest in contrast to published mouse data. Our findings underline the importance of developing reliable models and we propose the use of human whole blood models in pre-clinical screening of gene therapy vectors.

Interleukin-12 inhibits liver-specific drug-inducible systems in vivo.

Drug-inducible systems allow modulation of the duration and intensity of cytokine expression in liver immuno-based gene therapy protocols. However, the biological activity of the transgene may influence their function. We have analyzed the kinetics of interleukin-12 (IL-12) expression controlled by the doxycycline (Dox)- and the mifepristone (Mif)-dependent systems using two long-term expressing vectors directed to liver: a plasmid administered by hydrodynamic injection and a high-capacity adenoviral vector. Daily administration of Dox or Mif was associated with a progressive loss of inducibility and a decrease of murine IL-12 production. This inhibition occurred at the transcriptional level and was probably caused by an interferon (IFN)-gamma-mediated downmodulation of liver-specific promoters that control the expression of transactivators in these systems. Genome-wide expression microarrays studies revealed a parallel downregulation of liver-specific genes in mice overexpressing murine IL-12. However, a promoter naturally induced by IL-12 was also inhibited by this cytokine when placed in a plasmid vector. Interestingly, treatment with sodium butyrate, a class I/II histone deacetylase inhibitor, was able to rescue liver-specific promoter activity solely in the vector. We conclude that biologically active IL-12 can transiently inhibit the function of drug-inducible systems in non-integrative DNA vectors by reducing promoter activity, probably through IFN-gamma and protein deacetylation-dependent mechanisms.

Foamy virus--adenovirus hybrid vectors.

To confer adenovirus vectors (AdV), the feature of integration into the host cell genome hybrid vectors were characterized in vitro, which express vectors derived from the prototypic foamy virus (FV) in the backbone of a high-capacity AdV. FVs constitute a subfamily of retroviruses with a distinct replication pathway and no known pathogenicity. In the absence of envelope glycoprotein, the prototypic FV behaves like a retrotransposon, while it behaves like an exogenous retrovirus in its presence. Two principle types of vectors, which either allows the intracellular (HC-FAD-7) or, in addition, the extracellular (HC-FAD-2) pathway were constructed. In both chimeras the expression of the FV vector was controlled by the tetracycline-regulatable system. Hybrids were produced close to 10(10) infectious units/ml. By Southern blotting, the functionality of the hybrid vectors to generate host cell genomic integrants was shown. However, the efficiency of HC-FAD-7 to establish stable transgene expression was rather low, while around 70% of cells were stably transduced in secondary round following primary transduction with HC-FAD-2 at an MOI of 100. Given the benign characteristics of high-capacity adenovirus and FV vectors, hybrids based on HC-FAD-2 are probably suited for an in vivo application.

Intracerebral transplantation and successful integration of astrocytes following genetic modification with a high-capacity adenoviral vector.

To investigate the ability of genetically modified astrocytes to integrate into adult rat brain, two spontaneously immortalized cell lines and the allogenic nontumorigenic glioma cell line F98 were transduced with a high-capacity adenoviral vector (HC-Adv) expressing the EGFP gene from the hCMV promoter. In organotypic slice cultures the transduced astrocytes were shown to integrate into the brain tissue. Following transplantation of the transduced astrocytes into the striatum of adult rats, the transplanted cells survived at least for 6 weeks, continuously expressed the EGFP transgene, in close neighborhood with cells of the recipient tissue executing their differentiation capacity along the glial lineage. Thus, HC-Adv transduced astrocytes are promising vehicles to locally deliver therapeutic proteins for the treatment of neurodegenerative diseases.

Comparison of long-term transgene expression after non-viral and adenoviral gene transfer into primary articular chondrocytes.

Different gene transfer approaches to achieve long-term transgene expression in cultured primary bovine chondrocytes were compared using enhanced green fluorescent protein (EGFP) as a reporter. Transduction with a high-capacity adenoviral vector was 82% efficient when analysed by fluorescence microscopy, while up to 42% of plasmid-transfected cells were EGFP positive with FuGene as a transfection reagent. Rapid dominant marker selection of plasmid-transfected cells was achieved in monolayer culture. With either method of gene transfer, a high proportion of the chondrocytes remained transgene positive during prolonged alginate culture. Transgene transcription in single cells was quantified with a confocal laser scanning microscope. Detection of EGFP expression was more sensitive with this method, identifying more transgene-expressing cells than conventional fluorescence microscopy. Long-term EGFP expression was higher in adenovirally transduced chondrocytes embedded in alginate as compared to plasmid-transfected cells cultured in monolayer or in alginate. Both the adenoviral and the plasmid-based approach appear suited for studies of the molecular and cellular mechanisms by which mutations in cartilage matrix proteins cause disease.

Local high-capacity adenovirus-mediated mCTLA4Ig and mCD40Ig expression prolongs recombinant gene expression in skeletal muscle.

Multiple forms of muscular dystrophy are due to the absence of cytoskeletal muscle proteins that normally protect the integrity of muscle cells. The lack of any adequate treatments for these devastating diseases propels research toward the development of strategies for gene delivery to skeletal muscle. High-capacity adenoviral vectors (HC-AdV) devoid of all viral coding sequences have been developed to avoid expression of viral proteins by the gene therapy vector. However, the capsid proteins that are an essential component of the input viral vector and any residual helper virus in the vector preparation could induce an immune response. Furthermore, the therapeutic protein provided by a gene transfer vector presents the potential to induce an immune response in a patient who does not express a normal cellular protein due to genetic mutation. Therefore, we hypothesize that some immune suppression will be required with therapeutic gene delivery designed for the treatment of patients with inherited muscle diseases. In this study, we constructed and rescued three HC-AdVs expressing murine CTLA4Ig, murine CD40Ig, or both. The backbone vector without a gene insert was rescued as a negative control vector. The production of relevant proteins from each vector was determined in vitro. In vivo function of each of the immunosuppressant vectors was assayed by co-injection with an enhanced green fluorescent protein (EGFP)-expressing first-generation adenoviral vector (AdEGFP) into the tibialis anterior muscle of C57BL/10 mice. Higher levels of muscle EGFP expression were observed in animals receiving an immunosuppressant vector. Furthermore, the production of total anti-AdV and anti-EGFP antibodies was reduced in mice treated with each of the three immunosuppressant vectors. A second intramuscular administration of AdEGFP alone 4 weeks after the initial co-injection was successful in all immunosuppressant vector-treated groups, but not in the negative control vector-treated group. All groups had a high antibody response to adenoviral proteins after the second injection of AdEGFP alone, indicating that the initial co-injection did not tolerize against vector capsid antigens.

The X-linked inhibitor of apoptosis (XIAP) prevents cell death in axotomized CNS neurons in vivo.

The inhibition of neuronal apoptosis in acute traumatic and ischemic injuries as well as in long term neurodegenerative disorders like spinal muscular atrophy and possibly Alzheimer's disease is a fundamental requirement for a therapeutic strategy. In this study we used an established in vivo model system of induction of neuronal apoptosis in the CNS to evaluate the properties of the X-linked inhibitor of apoptosis protein (XIAP) to inhibit secondary cell death after axonal lesions. We used adenoviral vectors to transduce retinal ganglion cells after axotomy of the optic nerve of adult rats. Vector application was performed at the optic nerve stump so that only the lesioned retinal neurons could be transduced. We found XIAP to be as effective as the viral broad spectrum caspase inhibitor protein p35. These findings suggest that axotomized RGCs degenerate through class II caspase activity and furthermore offer the possibility of using mammalian XIAP protein to inhibit neuronal apoptosis as a basis for a regenerative therapy in the CNS.