Retroviral-mediated gene transfer. Applications in neurobiology

Retrovirus-mediated gene transfer of transthyretin and transthyretin-methionine 30: a potential tool for the study of amyloidogenesis

Familial amyloidotic polyneuropathy (FAP) is a genetic disease characterized by systemic amyloid deposition particularly in the peripheral nervous system. These deposits are composed mainly of a mutant form of the serum protein transthyretin (TTR) having a methionine for valine substitution at position 30-TTR Met 30. The factors involved in the formation of these deposits are unknown. The existence of animal models for FAP should allow elucidation of these factors. As one approach to the development of animal models for amyloidogenesis in FAP, we have constructed recombinant retrovirus vectors, carrying the full length human cDNA for either TTR or TTR Met 30 under the control of the Moloney murine leukemia virus (MoMLV) LTR element. After transfection of the packaging cell line, psi 2, viral stocks were used to infect a rat hepatoma cell line, H56, mouse fibroblast cell line, NIH3T3, and mouse primary fibroblasts. H56 cells efficiently secreted both TTR and TTR Met 30 as assessed by immunoprecipitation and ELISA, whereas NIH3T3 fibroblasts appeared not to release these proteins under the conditions tested. Primary fibroblasts secreted the mutant protein as assessed by ELISA. These genetically modified cells can be grafted into animals for in vivo study of amyloidogenesis, as well as be used in culture to investigate factors that might regulate the rate of amyloid deposition.

Gene transfer into mammalian somatic cells in vivo

Direct gene transfer into mammalian somatic tissues in vivo is a developing technology with potential application for human gene therapy. During the past 2 years, extensive progress and numerous breakthroughs have been made in this area of research. Genetically engineered retroviral vectors have been used successfully to infect live animals, effecting foreign gene expression in liver, blood vessels, and mammary tissues. Recombinant adenovirus and herpes simplex virus vectors have been utilized effectively for in vivo gene transfer into lung and brain tissues, respectively. Direct injection or particle bombardment of DNA has been demonstrated to provide a physical means for in situ gene transfer, while carrier-mediated DNA delivery techniques have been extended to target specific organs for gene expression. These technological developments in conjunction with the initiation of the NIH human gene therapy trials have marked a milestone in developing new medical treatments for various genetic diseases and cancer. Various in vivo gene transfer techniques should also provide new tools for basic research in molecular and developmental genetics.

Infection with murine retrovirus confers resistance to the neurotoxin 1-methyl-4-phenylpyridinium ion in PC 12 cells

High concentrations of the dopaminergic neurotoxin 1-methyl-4-phenylpyridinium ion (MPP+) are toxic to the catecholaminergic cell line PC12, derived from rat phenochromocytoma. Prolonged exposure of wild-type PC12 cells to 500 microM MPP+ yields toxin-resistant colonies at a frequency of 2 X 10(-4). These spontaneously arising MPP(+)-resistant cells are morphologically quite distinct from wild-type PC12 cells, and are lacking in most of their characteristic catecholaminergic properties. In contrast, among PC12 cells infected with the murine retrovirus ZIPNEOSV(X), 20% are resistant to the toxin MPP+, a resistance frequency approximately 1,000 times higher than for uninfected cells. The morphology and catecholaminergic phenotype of the virus-infected MPP+ resistant cells are quite similar to those of wild-type PC12 cells. The results presented in this study suggest a unique mechanism of MPP+ resistance in the infected PC12 cells which may be conferred by the presence and/or expression of the retrovirus ZIPNEOSV(X).