Growth of human melanoma xenografts is suppressed by systemic angiostatin gene therapy.

The effect of local and systemic delivery of the angiostatin gene on human melanoma growth was studied in nude mice. Liposome-coated plasmids carrying the cDNA coding for murine and human angiostatin (CMVang and BSHang) were injected weekly, locally or systemically, in mice transplanted with melanoma cells. The treatment reduced melanoma growth by 50% to 90% compared to that occurring in control animals treated with liposome-coated plasmid carrying the lacZ gene or in untreated controls. The growth of both locally injected and controlateral uninjected tumors in mice bearing two melanoma grafts was significantly suppressed after intratumoral treatment. Tumor growth inhibition was also observed in mice treated by intraperitoneal delivery, suggesting that angiostatin gene therapy acts through a systemic effect. Both melanoma growth suppression and delay in the onset of tumor growth were observed in treated mice. PCR performed on tumors and normal tissues showed that the lipofected DNA was present in tissues from treated mice, and angiostatin expression was demonstrated by RT-PCR. Histopathological analysis of melanoma nodules revealed an increase in apoptotic cells and a reduction in vessel density in tumors from treated mice. Our results suggest that systemic, liposome-mediated administration of genes coding for antiangiogenic factors represents a promising strategy for melanoma treatment in humans.

Systemic gene therapy with anti-angiogenic factors inhibits spontaneous breast tumor growth and metastasis in MMTVneu transgenic mice.

Tumor growth and metastasis are angiogenesis-dependent. The possibility of inhibiting tumor growth by interfering with the formation of new vessels has recently raised considerable interest. We previously reported that it is possible to inhibit primary tumor growth and metastasis in a transgenic model of spontaneous breast tumor, which shows many similarities to its human counterpart (including ability to metastasize) by intratumoral administration of a DNA construct carrying the murine angiostatin cDNA driven by liposomes. Here we report that it is also possible to achieve this goal by a systemic (intraperitoneal) delivery of therapeutic DNA constructs carrying genes coding for mouse and human anti-angiogenic factors which include angiostatin, endostatin and TIMP-2. These findings may be relevant to the design of therapeutic interventions in humans.

Lymphoid abnormalities in CD40 ligand transgenic mice suggest the need for tight regulation in gene therapy approaches to hyper immunoglobulin M (IgM) syndrome.

Mutations in the CD40 ligand (CD40L) are responsible for human hyper immunoglobulin M (IgM) syndrome. The absence of the interaction between CD40L, expressed by T lymphocytes, and the CD40 receptor present on the surface of B cells is responsible for the inability of B cells to carry out the isotype switch from IgM to the other Ig classes. This leads to a fatal immunodeficiency for which no cure exists. For these reasons, the CD40L gene is a good candidate for gene therapy studies. To investigate the possible effects of the expression of this tightly regulated gene in vivo, we produced transgenic mice in which CD40L expression was deregulated. Widespread ectopic expression appears to be lethal. Overexpression in mature T cells is compatible with life, but in one-third of the cases, mice developed atypical lymphoid proliferations which, occasionally, progressed into frank lymphomas. Even though gene therapy is one of the most promising approaches to cure human hyper IgM syndrome, these results suggest that when we modify very tightly regulated genes such as cytokines or other growth factors, particular care has to be taken to avoid excessive stimulation of the target cells.

Liposome-delivered angiostatin strongly inhibits tumor growth and metastatization in a transgenic model of spontaneous breast cancer.

The possibility to inhibit tumor growth by interfering with the formation of new vessels, which most neoplasias depend on, has recently raised considerable interest. An angiogenic switch, in which proliferating cells acquire the ability to direct new vessel formation, is thought to be an early step in the natural history of solid tumors. Using a transgenic model of breast cancer, which shows many similarities to its human counterpart, including ability to metastasize, we targeted angiostatin production to an early stage of tumor formation. Liposome-delivered angiostatin considerably delayed primary tumor growth and, more importantly, inhibited the appearance of lung metastases. These findings can be relevant to the design of therapeutic intervention in humans.

Retrovirus-mediated IL-4 gene therapy in spontaneous adenocarcinomas from MMTV-neu transgenic mice.

Gene therapy approaches to the treatment of experimental cancer are usually based on established neoplastic cell lines which are manipulated in vitro and subsequently transplanted in host animals. However, the relevance of these artificial models to the biology and therapy of human tumors is uncertain. We have previously validated an experimental model based on MMTV-neu transgenic mice in which breast tumors arise spontaneously in 100% of animals and have many features in common with their human counterpart, including the involvement of the neu oncogene and the ability to metastatize. In this article we report the effect of intratumoral, retrovirus-mediated, IL-4 expression on the growth of breast tumors arising in these mice. The size of IL-4 inoculated tumors on the right side was significantly smaller than that of controlateral untreated tumors, suggesting a local effect of IL-4. In addition, the non-injected tumors on the left side of treated animals were significantly smaller than those arising in control transgenic mice, suggesting that IL-4 can also inhibit tumor growth systemically. These findings suggest that IL-4 gene transfer can significantly reduce the growth rate of spontaneously arising breast tumors and that immune-based gene therapy could efficiently complement other approaches based on different mechanisms, such as suicide gene transfer or antisense technology.

A transgenic mouse model for the detection of cellular stress induced by toxic inorganic compounds.

Transgenic mice for genotoxicity testing have been developed, although no such models have been produced for the evaluation of toxic, nongenotoxic chemical compounds. We have developed a transgenic mouse model for the analysis of toxic inorganic compounds. We engineered a mouse lineage with the human growth hormone (hGH) gene under the control of the human hsp70 promoter, in which a plasma-detectable hGH response can be elicited by exposure to heat shock. In primary cell cultures from these mice, hGH release was observed following treatment with several toxic inorganics. Transgenic mice injected intraperitoneally with sodium arsenite, cadmium chloride, copper sulphate, or methylmercurium chloride showed significant hGH levels in plasma.