Retrovirus-mediated gene transfer into canine thyroid using an ex vivo strategy

Use of recombinant herpes simplex virus type 1 vectors for gene transfer into tumour and normal anterior pituitary cells

In this paper we demonstrate the use of recombinant viral vectors derived from herpes simplex virus type 1 (HSV1) to transfer reporter genes in vitro into rat anterior pituitary cells grown in primary cultures and the anterior pituitary tumour cell lines GH3 and AtT20. The three vectors used were, tsK/beta-galactosidase (beta-gal), tsK/CRH and tsK/TIMP, the corresponding transgene products respectively being E. coli beta-gal, pre-procorticotropin releasing hormone (ppCRH), and the chimeric protein TIMP/Thy1 (tissue inhibitor of metalloproteinases (TIMP)/linked to the carboxy terminus of Thy1 which confers the addition of a glycolipid glycosyl-phosphatidylinositol anchor in the ER). Double labelling immunofluorescence experiments to detect reporter proteins and transduced cell types indicated that the three vectors could transfer and express the reporter genes in normal and tumour anterior pituitary cells. Virus infection of pituitary cells was characterised, and it was shown that infection with tsK/beta-gal at multiplicities of infection (MOI)=10, 100% of tumour and non-endocrine anterior pituitary cells expressed beta-gal, whereas 75% endocrine anterior pituitary cells expressed the transgene. Long-term expression studies after infection with tsK/beta-gal indicated that anterior pituitary cells in primary cultures expressed the transgene for significant longer periods than tumour anterior pituitary cells. Growth arrest by serum starvation markedly decreased the frequency of transgene expression in anterior pituitary cells following infection with tsK/beta-gal. Transgenic products expressed from tsK were targeted to their correct intracellular domain in both anterior pituitary cells in primary cultures and in pituitary tumour cell lines. We conclude that transgenes can be delivered into anterior pituitary cells in primary culture and pituitary tumour cell lines using tsK derived HSV1 vectors. The prospect of employing viral vectors to transfer genes into endocrine cells opens up the potential exploration of various molecular aspects of pituitary cell function both in vitro and in vivo, as well as the use of gene transfer into the pituitary for potentially therapeutic applications, such as the treatment of pituitary tumours.

Osteoprogenitor cells as targets for ex vivo gene transfer

We transduced osteoprogenitor cells with recombinant retrovirus and analyzed proviral integration patterns into chromosomal DNA to detect for the first time the clonal and cellular fate of osteoprogenitor-derived progeny cells. Metaphyseal bone cells and diaphyseal stromal cells were isolated from the distal femurs of young rats, transduced with the vM5neolacZ recombinant retrovirus, and selected in the neomycin analog, G418. Following surgical marrow ablation of a femur in one leg of mature rats, retroviral-transduced metaphyseal or diaphyseal cells were injected into the ablated site. These rats were killed 5-6 days later. Metaphyseal and diaphyseal cells were isolated from distal femurs, selected in G418, and stained for beta-galactosidase (beta-gal+). The number and clonal origin of transduced progenitor cells were determined. High numbers of beta-galactosidase colonies with an osteoblast phenotype were obtained following metaphyseal transplants and detected in 100% of metaphyseal and none of diaphyseal specimens. In contrast, beta-galactosidase colonies derived from diaphyseal transplants were detected in 50% of specimens in both the metaphysis and diaphysis, and the absolute number of progenitor cell colonies was 60-fold less than metaphyseal transplants. Provirus was only detected in the ablated bones and not in the contralateral bone or other tissues. Proviral integration fragment analysis showed a single integration site for recovered metaphyseal cell clones, consistent with their origination from a common single progenitor. This is one of the first demonstrations of successful transplantation of clonal osteoprogenitors to their site of origin in bone. It may be possible to use these cells to target genes to bone for therapeutic use in skeletal and hematopoietic diseases.

Adenoviral infection of thyroid cells: a rationale for gene therapy for metastatic thyroid carcinoma

BACKGROUND

Patients with thyroid carcinoma experience excellent long-term survival; however, up to 16% will die of their disease. We have transformed a rat thyroid follicular cell line (FRTL-5) with a gene (TGCT) that mimics a known mutation associated with thyroid neoplasms. These cells form subcutaneous tumors that metastasize to lung in nude mice.

METHODS

In anticipation of developing gene therapy against this thyroid carcinoma model, we (1) tested whether adenovirus containing the beta-galactosidase gene could infect FRTL-5 cells and neonatal rat thyroid and (2) evaluated the ability to kill FRTL-5 cells by transfecting them with a transgene in which the thyroglobulin promoter (TG) directed the expression of herpes simplex virus type I thymidine kinase (HSV1TK) and treating TG-HSV1TK-transfected cells with 5 micrograms/ml ganciclovir.

RESULTS

Nearly 100% of the TG-HSV1TK but only 5% of control cells were killed by addition of ganciclovir. Histochemical staining for beta-galactosidase activity demonstrated infection of FRTL-5 cells and neonatal rat thyroid tissue by adenovirus beta-galactosidase.

CONCLUSIONS

These data demonstrate the feasibility of using adenovirus as vector to infect thyroid cells in vivo and provide a rationale for development of gene therapy for treatment of thyroid cancer.

Development and analysis of retroviral vectors expressing human factor VIII as a potential gene therapy for hemophilia A

To develop a potential gene therapy strategy for the treatment of hemophilia A, we constructed several retroviral vectors expressing a B-domain-deleted factor VIII (FVIII) cDNA. We confirmed previous reports that when the FVIII cDNA is inserted into a retroviral vector, the vector mRNA is decreased resulting in significantly (100- to 1,000-fold) lower vector titers. In an attempt to overcome this inhibition we pursued two independent strategies. First, site-directed mutagenesis was employed to change the structure of a putative 1.2-kb FVIII RNA inhibitory sequence (INS). Second, the FVIII gene was transcribed from a retroviral vector containing a 5' intron. Results demonstrated that the intron increased FVIII expression up to 20-fold and viral titer up to 40-fold but conservative mutagenesis of the putative FVIII INS region failed to yield a significant increase in FVIII expression or titer. Using the improved FVIII splicing vector, we transduced a variety of cell types and were able to demonstrate relatively high FVIII expression (10-60 ng of FVIII/10(6) cells/24 hr). These results underscore the usefulness of these transduced cell types for potential in vivo delivery of FVIII.

Gene therapy in surgical oncology

BACKGROUND

Surgery remains the only potentially curative treatment modality for the majority of patients with solid tumors. Conventional chemotherapy and radiotherapy only have roles as adjuvant or palliative therapies for most common cancers. Two decades of research have led to the first attempts at producing and introducing clinically useful genetically modified cells into humans.

METHODS

Modern molecular methods have been developed that allow the stable transfer of foreign DNA sequences into human and other mammalian somatic cells. At the present time, gene therapy predominantly involves gene insertion either directly into a target cell in situ or into an appropriate cell in vitro that is then introduced to a physiologically relevant site. We present an overview of the potential applications of molecular biology for practicing surgeons, particularly in the field of surgical oncology, to show how genes are harnessed and inserted into target somatic cells.

CONCLUSIONS

Although significant clinical therapies have and will continue to emerge from these initial experiments, only the future will provide evidence of whether the present technical skills are sufficient to have an impact on the long-term benefits for patients with cancer and genetic defects.

In vivo gene transfer into rabbit thyroid follicular cells by direct DNA injection

Direct injection of DNA expression vectors into muscle leads to expression of encoded recombinant gene products in mature muscle cells. This phenomenon is not shared by most other organs. We have surveyed various organs in the rabbit to identify other cell types that would express DNA vectors after direct injection. We observed that thyroid follicular cells were capable of acquiring plasmid DNA and expressing recombinant gene products after direct interstitial injection of plasmid vectors into the thyroid gland. The level of expression of a chloramphenicol acetyltransferase (CAT) reporter gene in thyroid tissue was similar to that seen in muscle tissue three days after injection in controlled experiments. Using a beta-galactosidase reporter gene, expression was localized to thyroid follicular cells. CAT activity decreased with first-order kinetics and a half-life t1/2 of 40 hr. DNA was identified in thyroid tissue by polymerase chain reaction (PCR) analysis and displayed first-order elimination kinetics with a half-life t1/2 of 10 hr. The persistence of the gene and gene product in the thyroid was significantly different from that observed after injection of DNA vectors into muscle or delivery of DNA vectors to the liver using asialoglycoprotein/polylysine/DNA complexes, suggesting that there are significant differences in the process of DNA uptake or compartmentalization in these experimental systems. These results introduce the possibility of developing the thyroid as a novel target for treating certain thyroid or systemic diseases using DNA vectors.