Bigger Is Better Than Many: A Strategy to Optimize Multi-Gene Co-Expression

Large plasmids are often avoided in mammalian co-transfection due to the assumption that they transfect poorly, driving the use of multiple smaller plasmids. Here, we pair finite-state-projection modeling with flow cytometry experiments to compare one-, two-, and three-plasmid delivery of GFP/BFP/RFP. Estimated entry rates were size-independent from 4.9 to 16.4 kb, indicating that plasmid length is not the dominant barrier in this range. Our results suggest that using lipofectamine slightly increases co-transfection efficiency due to the ability of lipoplexes to contain multiple plasmids. However, this benefit is limited to only delivering two plasmids. Additionally, we show that contrary to current beliefs, putting all genes onto the same plasmid both increases the probability that a cell will express all genes of interest and results in a tighter correlation of gene expression levels compared to these multi-plasmid systems. Together, these results identify multi-cargo delivery and not plasmid size as the key constraint on co-transfection and show that single-plasmid designs are generally preferable for applications such as viral-vector production.