Development of Transgenic Livestock with Reduced Myostatin Expression Using RNA Interference

RNA interference (RNAi) is a means of regulating gene expression by targeting mRNA in a sequence-specific manner for degradation or translational inhibition. Short hairpin RNAs (shRNAs) and short interfering RNAs (siRNAs) have been extensively employed for manipulating gene expression in a wide range of species. The goal for this research was to produce transgenic livestock in which myostatin, a negative regulator of muscle growth, has been targeted for silencing by RNAi. This would demonstrate the utility of RNAi for reducing gene expression in large animal species. To successfully target the myostatin gene for reduction, siRNAs were designed to target the both the bovine and caprine myostatin mRNA sequence. These were then tested for effectiveness in vitro using both an HEK 293T cell line expressing caprine myostatin as well as adult bovine muscle cells. The most effective siRNA, GDF8-1026, was cloned into a lentiviral plasmid and used to transduce bovine fetal fibroblasts for somatic cell nuclear transfer cloning as well as perivitelline injection of in vitro produced bovine embryos. To date, seven pregnancies have been established using these two methods. Concern over the possibility of off-target effects associated with the expression of shRNAs in vivo prompted investigation into tissue-specific expression. Therefore, investigation into the use of a muscle-specific promoter to drive transgene expression was pursued. The bovine myogenin promoter and muscle creatine kinase (MCK) promoter were cloned into a lentiviral plasmid and evaluated in bovine fetal muscle cells and mouse C2C12 cells in vitro for their ability to drive GFP expression. Both promoters demonstrated an increase in GFP intensity at day nine of differentiation when compared to the nontransduced control. The retroviral basis of lentiviral plasmids has raised concern over the possible development of replication competent lentivirus (RCL). Therefore, analysis of tissues from recipients of lentivirus-treated embryos was performed to detect possible RCL. Tissues and blood serum were tested for RCL using p24 ELISA as well as qRT-PCR for the VSV-G gene. To date all tissues tested so far shown no evidence for RCL using these analyses. Analysis of offspring transgenic for an shRNA targeting myostatin will allow confirmation of RNAi as a useful tool for manipulating gene expression in large animal species.