Plasmid transfection and retroviral transduction of porcine muscle cells for cell-mediated gene transfer

Cell-mediated gene transfer is a potential tool for studying muscle growth, but efficient genetic manipulation and implantation strategies have not been developed for pigs. The objectives of the present study were to determine methods for transient and stable incorporation of reporter genes into porcine muscle cells and to investigate their use for cell-mediated gene transfer in pigs. Porcine myoblasts and fibroblasts were isolated from muscle of 2-wk-old male pigs. Myogenic cell lines were identified using muscle-specific monoclonal antibodies, myotube fusion assays, and the presence of muscle-specific markers (MyoD and desmin). Four commercial cationic liposomes (lipofectAMINE, lipofectin, cellFECTIN, and DMRIE-C) were tested at different DNA:lipid ratios for their ability to transfect myoblasts and fibroblasts transiently with a luciferase reporter plasmid. LipofectAMINE resulted in the greatest (P < .01) transient luciferase activity for both cell types. Electroporation of cells for transient transfection resulted in less luciferase activity than cationic transfection. Stable transfections were conducted using a green fluorescence protein (GFP) reporter plasmid containing the neomycin resistance gene. LipofectAMINE transfection resulted in stable GFP expression in 1:16,000 myoblasts and 1:33,000 fibroblasts. Stable electroporation resulted in efficiencies that were significantly lower than established with cationic liposomes. Porcine cells were transduced with GFP using vesicular stomatitis virus glycoprotein G pseudotyped retrovirus and resulted in efficiencies of 1:1.2 for myoblasts and 1:1.1 for fibroblasts. These results show that cationic liposomes are superior to electroporation for transfection, but retroviral transduction produced stable reporter gene expression in > 80% of porcine muscle cells. Transduced GFP-positive cells were separated from GFP-negative cells by fluorescence-activated cell sorting and implanted into 2-wk-old male pigs. On d 4, implanted muscles were removed and subjected to immunodetection of GFP protein. Fibroblast implantation resulted in limited GFP expression within muscle, whereas myoblast implantation resulted in GFP within muscle fibers. This suggests that cell-mediated gene transfer is possible in porcine muscle and may be useful as an approach for studying muscle growth in pigs.