Evaluation of the effect of non-B DNA structures on plasmid integrity via accelerated stability studies

Plasmid biopharmaceuticals are a new class of medicines with an enormous potential. Attempts to increase the physical stability of highly purified supercoiled (SC) plasmid DNA in pharmaceutical aqueous solutions have relied on: (i) changing the DNA sequence, (ii) improving manufacturing to reduce deleterious impurities and initial DNA damage, and (iii) controlling the storage medium characteristics. In this work we analyzed the role of secondary structures on the degradation of plasmid molecules. Accelerated stability experiments were performed with SC, open circular (OC) and linear (L) isoforms of three plasmids which differed only in the ''single-strandlike'' content of their polyadenylation (poly A) signals. We have proved that the presence of more altered or interrupted (non-B) DNA secondary structures did not directly translate into an easier strand scission of the SC isoforms. Rather, those unusual structures imposed a lower degree of SC in the plasmids, leading to an increase in their resistance to thermal degradation. However, this behavior was reversed when the relaxed or L isoforms were tested, in which case the absence of SC rendered the plasmids essentially double-stranded. Overall, this work suggests that plasmid DNA sequence and secondary structures should be taken into account in future investigations of plasmid stability during prolonged storage.