The Effects of Magnesium, Zinc and Calcium Ions on Endotoxin-Plasmid DNA Interaction at Various Cation Concentrations, pH Values and Incubation Times

Abstract

In plasmid DNA (pDNA) production from Gram-negative bacteria, endotoxin has been known as the major contaminant. The separation becomes difficult due to its ability to form a stable complex with pDNA apart from sharing common properties like surface charge, molecular size, temperature, and pH stability. This study focused on the analysis of the zeta potential values of endotoxin, the theoretical number of cations bound per molecule of endotoxin as well as the binding tendency of cations towards endotoxin in the presence of pDNA. These analyses were conducted under various experimental conditions such as types of divalent metal cation, cation concentration, pH and incubation time. The analysis of zeta potential at different cation concentrations and pH values showed that Mg2+ had the most significant effect on endotoxin surface charge. The zeta potential of endotoxin was reduced by a magnitude of 43.55 mV, from −43.53 mV to 0.02 mV in the presence of 2.0 M Mg2+, and a magnitude of 44.12 mV, from −43.53 mV to 0.59 mV at the lowest pH level. However, in the analysis of the theoretical number of cations bound per molecule of endotoxin, Zn2+ showed the highest number (0.6) compared to Ca2+ (0.12) and Mg2+ (0.05). The tendency of Zn2+ to preferentially bind with endotoxins forming a larger aggregated structure was also evident in the DNA gel electrophoresis and transmission electron microscopic analysis. The manuscript highlights the significance of cations in the binding and aggregation of endotoxins, which ultimately improves the recovery of pDNA and affects its subsequent downstream processing.