Sustained gene expression in transplanted skin fibroblasts in rats

In vivo bone formation in fracture repair induced by direct retroviral-based gene therapy with bone morphogenetic protein-4

This study sought to develop an in vivo gene therapy to accelerate the repair of bone fractures. In vivo administration of an engineered viral vector to promote fracture healing represents a potential high-efficacy, low-risk procedure. We selected a murine leukemia virus (MLV)-based retroviral vector, because this vector would be expected to target transgene expression to the proliferating periosteal cells arising shortly after bone fracture. This vector transduced a hybrid gene that consisted of a bone morphogenetic protein (BMP)-4 transgene with the BMP-2 secretory signal to enhance the secretion of mature BMP-4. The MLV vector expressing this BMP-2/4 hybrid gene or beta-galactosidase control gene was administered at the lateral side of the fracture periosteum at 1 day after fracture in the rat femoral fracture model. X-ray examination by radiograph and peripheral quantitative computed tomography at 7, 14, and 28 days after fracture revealed a highly significant enhancement of fracture tissue size in the MLV-BMP-2/4-treated fractures compared to the control fractures. The tissue was extensively ossified at 14 and 28 days, and the newly formed bone exhibited normal bone histology. This tissue also exhibited strong immunohistochemical staining of BMP-4. Additional control and MLV-BMP-2/4-treated animals each were monitored for 70 days to determine the fate of the markedly enhanced fracture callus. Radiographs showed that the hard callus had been remodeled and substantial healing at the fracture site had occurred, suggesting that the union of the bone at the fracture site was at least as high in the BMP-4-treated bone as in the control bone. There was no evidence of viral vector infection of extraskeletal tissues, suggesting that this in vivo gene therapy for fracture repair is safe. In summary, we have demonstrated for the first time that a MLV-based retroviral vector is a safe and effective means of introducing a transgene to a fracture site and that this procedure caused an enormous augmentation of fracture bone formation.

Lentiviral vectors for efficient transduction of isolated primary quiescent hepatocytes

BACKGROUND/AIMS

Lentiviral vectors were designed to obtain efficient transduction of primary quiescent hepatocytes.

METHODS

A hepatitis B virus (HBV) fragment containing enhancers and posttranscriptional regulatory element was used to increase expression levels. The human immunodeficiency virus (HIV) central polypurine tract (PPT) was used to increase transduction of quiescent cells. HBV elements were incorporated downstream and the HIV PPT was incorporated upstream of green fluorescent protein expression cassettes in third generation self inactivating lentiviral vectors.

RESULTS

The HBV fragment increased mean fluorescence of transduced HepG2 hepatoma cells 4.3+/-1.7-fold and 2.3-6.0-fold in various other cell types. A role of HBV x protein in the function of the HBV element was excluded. The HBV element increased the number of transducing units per pg of HIV p24 twofold. The unmodified lentiviral vector transduced 5+/-1% of cultured quiescent primary rat hepatocytes, HBV elements increased transduction to 54+/-13% and increased fluorescence 2.8+/-0.6-fold. The PPT increased transduction to 47+/-11% and increased fluorescence 2.3+/-0.4-fold. The vector with PPT and HBV elements transduced 68+/-10% of hepatocytes and increased fluorescence synergistically, 17+/-6 fold.

CONCLUSIONS

This study shows that HBV elements or HIV PPT are required for efficient transduction of primary hepatocytes.

Development of disabled, replication-defective gene transfer vectors from the Jembrana disease virus, a new infectious agent of cattle

Jembrana disease virus (JDV) is a newly isolated and characterised bovine lentivirus. It causes an acute disease in Bali cattle (Bos javanicus), which can be readily transmitted to susceptible cattle with 17% mortality. There is as yet no treatment or preventive vaccine. We have developed a gene transfer vector system based on JDV that has three components. The first of the components is a bicistronic transfer vector plasmid that was constructed to contain cis-sequences from the JDV genome, including 5'- and 3'-long terminal repeats (LTRs), 0.4kb of truncated gag and 1.1kb of 3'-env, a multiple cloning site to accommodate the gene(s) of interest for transfer, and an internal ribosome entry site plus the neomycin phosphotransferase (Neo) gene cassette for antibiotic selection. The second element is a packaging plasmid that contains trans-sequences, including gag, pol, vif, tat and rev, but without the env and packaging signals. The third is a plasmid encoding the G glycoprotein of vesicular stomatitis virus (VSV-G) to supply the vector an envelope for pseudotyping. Cotransfection of 293T cells with these three plasmid components produced VSV-G pseudotyped, disabled, replication defective, bicistronic JDV vectors encoding the green fluorescent protein (EGFP) and the Neo resistance selection maker simultaneously with a titre range of (0.4-1.2)x10(6)CFU/ml. Transduction of several replicating primary and transformed cells from cattle, primate and human sources and importantly growth-arrested cells with the JDV vectors showed high efficiency of EGFP gene transfer at 35-75%, which was stable and the expression of EGFP was long term. Furthermore, these JDV vectors were designed to suit the inclusion and expression of genes corresponding to JDV specific proteins, such as gag or env, for the development of vaccines for Jembrana disease. This strategy should also be applicable to other bovine diseases as well. The design and construction of the JDV vector system should facilitate the study of the lentivirology and pathogenesis of the diseases associated with JDV or other bovine virus infections. To our knowledge, this is the first such vector system developed from a cattle virus.

VP22 enhanced intercellular trafficking of HSV thymidine kinase reduced the level of ganciclovir needed to cause suicide cell death

BACKGROUND

The inefficiency of herpes simplex virus thymidine kinase (TK) gene transfer and toxicity of ganciclovir (GCV) at high concentrations in vivo limits the use of this suicide gene therapy approach for the treatment of cancers in clinical settings. To overcome the problem, we have sought evidence of amplification of cytotoxicity by co-transfer of the TK gene fused with the gene encoding HSV-1 structural protein VP22 which has a remarkable ability for intercellular trafficking.

METHODS

The expression of the fusion proteins from the chimeric VP22-TK or VP22-EGFP genes was shown by Western blot and VP22 promoted TK or EGFP intercellular trafficking by an indirect immunofluorescent assay. The cytotoxicity was demonstrated by a colorimetric cell proliferation assay followed by an assessment of the bystander effect on admixtures of transfected with non-transfected naive cells.

RESULTS

Our results show the expression of the VP22 fusion proteins and their spread to varying numbers of bystander cells (up to 30, observed in viable cells with VP22-EGFP as well as after methanol fixation), confirming that VP22 assisted intercellular trafficking of the fusion proteins. This VP22 promoted TK spreading resulted in killing by 2.5 microg/ml GCV of virtually all cells in cultures that had been transfected at an efficiency of only 27.5%. In contrast, fewer than 80% of cells were killed when transfected with 'tk alone' at the same efficiency. The cell killing effect was exponentially dependent on GCV concentration in cells transfected with 'tk alone' at GCV concentrations between 0.25 and 0.5 microg/ml, but not those transfected with VP22-TK, probably due to the continuously variable, high sensitivity of about 50% of cells. Even at low concentration of GCV (0.2 microg/ml), the enhancement of cell killing by VP22 was four-fold higher in cells transfected with VP22-TK than in cells transfected with 'tk alone'.

CONCLUSIONS

VP22 enhanced intercellular trafficking of TK and amplified the TK/GCV killing effect, especially in the lower range of GCV concentrations. This offers a new strategy to enhance the effectiveness of suicide gene therapy for the treatment of cancers.

Glucose-regulated insulin expression in diabetic rats

Retroviral vectors encoding glucose-responsive promoters driving furin expression may provide an amplified, glucose-regulated secretion of insulin. We constructed LhI*TFSN virus to encode a glucose-regulatable transforming growth factor alpha promoter controlling furin expression with a viral LTR promoter driving constitutive expression of furin-cleavable human proinsulin. Autologous BB rat vascular smooth muscle cells transduced with LhI*TFSN virus and cultured in 1.7 and 16.7 mM glucose secreted 50.7 +/- 3.2 and 136.0 +/- 11.0 microU (mean +/- SD) of insulin per 10(6) cells per day, respectively. After the onset of diabetes spontaneously diabetic congenic DR lyp/lyp BB rats received stomach implants containing 2 x 10(6) LhI*TFSN-transduced primary rat vascular smooth muscle cells. In eight treated rats there was a major reduction in insulin requirement to as low as 25% of pretreatment level for up to 3 months and one rat became insulin free without hypoglycemia. Intraperitoneal glucose tolerance tests (IPGTTs) in diabetic rats receiving control implants did not show the characteristic decline in blood glucose of normal rats after glucose administration. In contrast, diabetic rats receiving LhI*TFSN-transduced cells showed significant clearances of blood glucose. These data suggest clinically significant levels of glucose-regulated insulin delivery from implanted vascular smooth muscle cells transduced with LhI*TFSN vector.

Fibroblasts and dermal gene therapy: a minireview

This review highlights our current understanding of the biology of, survival of, and transgene expression by genetically modified fibroblasts (GMFb) carrying stably integrated transgenes in vivo. Experimental data demonstrate that three elements will enhance expression by and survival of GMFb in vivo: a matrix scaffolding to take the place of the existing dermis, the presence of elements of the extracellular matrix in the construct used to move GMFb to the in vivo setting, and the utilization of immortalized fibroblasts to carry the transgenes. Although moving GMFb to an in vivo setting is an invasive procedure, there are a number of clinical settings where GMFb appear to be the suitable cell for gene therapy.

Novel bovine lentiviral vectors based on Jembrana disease virus

BACKGROUND

Safety is a concern that must be addressed prior to any clinical use of human immunodeficiency virus (HIV)-based lentiviral vectors in human patients. Unfortunately, efforts to examine the biosafety of the vectors in preclinical animal models are hampered due to the lack of animal models for HIV infection. We have developed new lentiviral vectors based on the recently characterised Jembrana Disease Virus (JDV), which infects a specific species of cattle naturally in Bali, Indonesia.

METHODS

Sequences from the JDV genome were amplified by splicing overlap extension polymerase chain reaction (PCR) for the construction of transfer vectors as well as a packaging construct. Co-transfection of these two plasmids into 293T cells with a third encoding a G glycoprotein of vesicular stomatitis virus produced pseudotyped, disabled, replication defective JDV vector particles. Viral titre was obtained by transducing the cells with the supernatant harvested from transfectants and determining the number of cells expressing the transgene. PCR and Southern blotting were used to detect the presence of potential replication-competent viruses as well as transgene integration.

RESULTS

Bicistronic JDV vectors encoding the green fluorescent protein (GFP) and the neomycin phosphotransferase were harvested with a titre range of 0.4-1.2 x 10(6) colony forming units/ml from vector-producing cells and were further concentrated by ultracentrifugation to the high titre of approximately 10(7) CFU/ml. Vectors encoding GFP were shown to transduce and integrate efficiently into the chromosomes of a range of primary and transformed cells of different origins in different differentiation status, including growth-arrested cells, with an efficiency of 25-75%. Exhaustive testing with a marker gene transfer assay in combination with a reverse transcriptase assay and PCR amplification of samples of serially passaged, transduced cells showed that no detectable amount of replication competent lentivirus (RCL) was produced.

CONCLUSIONS

We showed the feasibility of the development of gene transfer vectors based on a non-primate bovine lentivirus, which will provide the opportunity for examination of the efficacy and biosafety of lentiviral vector-mediated gene transfer in vivo in animal models. JDV-based vectors may be applicable and more readily acceptable than those from HIV for human gene therapy.