Multimerization of restriction fragments by magnesium-mediated stable base pairing between overhangs: a cause of electrophoretic mobility shift.

The electrophoretic mobility shift assay (EMSA) or simply the "gel shift assay" is one of the most sensitive methods for studying the ability of a protein to bind to DNA. EMSAs are also widely used to investigate protein- or sequence-dependent DNA bending. Here we report that electrophoresis using physiological concentrations of Mg(2+) can cause a mobility shift of restriction fragments in nondenaturing polyacrylamide gels as the overhangs form stable base pairs. This phenomenon was observed at even 37 degrees C. The retardation was, however, more pronounced at low temperatures, where a three-nucleotide overhang 5'-GAC also caused a mobility shift. The stability of the pairing was generally high when the overhangs of four nucleotides display high GC content, while the mobility shift caused by 5'-AATT was greater than those caused by 5'-GATC, 5'-TCGA, and 5'-CTAG. This observation should be taken into account to avoid misinterpretation of the data when the EMSA, especially the circular permutation gel mobility shift assay, is performed using a running buffer that contains Mg(2+) ions. The stable adhesion between short overhangs may present an important basis for genome stability and many genetic processes occurring in living cells.