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The free solution mobility of DNA in Tris‐acetate‐EDTA buffers of different concentrations, with and without added NaCl
Author(s) -
Stellwagen Earle,
Stellwagen Nancy C.
Publication year - 2002
Publication title -
electrophoresis
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.666
H-Index - 158
eISSN - 1522-2683
pISSN - 0173-0835
DOI - 10.1002/1522-2683(200206)23:12<1935::aid-elps1935>3.0.co;2-#
Subject(s) - tris , chemistry , dna , chromatography , inorganic chemistry , biochemistry
Abstract The free solution mobility of a high‐molecular‐weight DNA, linear pUC19, and a 20‐bp oligomer called dsA5 have been studied as a function of Tris‐acetate‐EDTA (TAE) buffer concentration, with and without added NaCl. The two DNAs migrate as separate peaks during capillary electrophoresis, because the mobility of linear pUC19 is higher than that of the 20‐bp oligomer. In TAE buffers ranging from 10–400 m M in concentration, the migration times and peak areas of the two DNAs are independent of whether they are electrophoresed separately or in mixtures, indicating that DNA‐DNA and DNA‐buffer interactions are absent in these solutions. The migration times of the two DNAs vary and the peak areas are not additive when the TAE buffer concentration is reduced to 5 m M or below, indicating that DNA‐DNA and DNA‐buffer interactions are occurring at very low TAE buffer concentrations. The mobilities of linear pUC19 and dsA5 decrease slowly with increasing conductivity or ionic strength when the conductivity is increased by increasing the TAE buffer concentration. When the Tris buffer concentration is held constant and the conductivity is increased by adding various concentrations of NaCl to the solution, the mobilities of linear pUC19 and dsA5 first increase slightly, then become independent of solution conductivity (or ionic strength), and finally decrease when the NaCl concentration is increased above ∼ 50 m M . The mobility variations observed in the various TAE and TAE‐NaCl solutions are described qualitatively by Manning’s theory, although quantitative agreement is not achieved. The free solution mobilities of single‐stranded pUC19 and two 20‐base oligonucleotides have also been measured. The free solution mobility of single‐stranded pUC19 is ∼15% lower than that of native pUC19, in agreement with other results in the literature. Somewhat surprisingly, the mobilities of the single‐ and double‐stranded 20‐mers are equal to each other in TAE buffers with and without added NaCl.