DNA uptake and repair enzyme access to transfected DNA is under reported by gene expression.

Gene expression is the typical biological end point of interest following transfection. However, transcription may not accurately assess DNA uptake, or the ability of transfected DNA to be acted on by other enzymatic pathways. We have compared DNA uptake to gene expression and the unrelated enzymatic process of DNA double strand break (DSB) repair. Transfection efficiency (at limiting DNA concentration) was assessed as a function of DNA uptake and gene expression in the DSB repair proficient WI38VA13 and MO59K cell lines and the DSB repair defective cell line MO59J, by comparing eGFP expression from the pHygEGFP expression vector with uptake of rhodamine labeled linear pSP189 plasmid (3:1). Repair proficient cells expressed eGFP most efficiently, but never approached DNA uptake levels (>or=90%). Although transfected DNAs were stable in repair proficient cells and degraded in MO59J cells, most cells did not express eGFP, but in the repair proficient cells linear DNA did undergo DSB repair.

Repair of radiation-induced DNA double-strand breaks is dependent upon radiation quality and the structural complexity of double-strand breaks.

Mammalian cells primarily repair DSBs by nonhomologous end joining (NHEJ). To assess the ability of human cells to mediate end joining of complex DSBs such as those produced by chemicals, oxidative events, or high- and low-LET radiation, we employed an in vitro double-strand break repair assay using plasmid DNA linearized by these various agents. We found that human HeLa cell extracts support end joining of complex DSBs and form multimeric plasmid products from substrates produced by the radiomimetic drug bleomycin, 60Co gamma rays, and the effects of 125I decay in DNA. End joining was found to be dependent on the type of DSB-damaging agent, and it decreased as the cytotoxicity of the DSB-inducing agent increased. In addition to the inhibitory effects of DSB end-group structures on repair, NHEJ was found to be strongly inhibited by lesions proximal to DSB ends. The initial repair rate for complex non-ligatable bleomycin-induced DSBs was sixfold less than that of similarly configured (blunt-ended) but less complex (ligatable) restriction enzyme-induced DSBs. Repair of DSBs produced by gamma rays was 15-fold less efficient than repair of restriction enzyme-induced DSBs. Repair of the DSBs produced by 125I was near the lower limit of detection in our assay and was at least twofold lower than that of gamma-ray-induced DSBs. In addition, DSB ends produced by 125I were shown to be blocked by 3'-nucleotide fragments: the removal of these by E. coli endonuclease IV permitted ligation.