Fluorescently labeled circular DNA molecules for DNA topology and topoisomerases

DNA topology plays essential roles in several fundamental biological processes, such as DNA replication, recombination, and transcription. Typically agarose gel electrophoresis is employed to study DNA topology. Since gel electrophoresis is time-consuming and labor intensive, it is desirable to develop other methods, such as fluorescence-based methods, for such studies. In this paper we report the synthesis of a type of unique fluorescence-labeled DNA molecules that can be used to study DNA topology and topoisomerases by fluorescence resonance energy transfer (FRET). Specifically, we inserted an 82 nt. synthetic DNA oligomer FL905 carrying a 42 nt. AT sequence with fluorescein and dabcyl labels into a gapped DNA molecule to generate relaxed and supercoiled pAB1_FL905. Since the fluorescence intensity of pAB1_FL905 is dependent on its supercoiling status, pAB1_FL905 is a powerful tool to study DNA topology and topoisomerases by FRET. pAB1_FL905 can also be developed into rapid and efficient high-throughput screening assays to identify inhibitors that target various DNA topoisomerases

Biochemical and biophysical properties of positively supercoiled DNA

In this paper we successfully developed a procedure to generate the (+) supercoiled (sc) plasmid DNA template pZXX6 in the milligram range. With the availability of the (+) sc DNA, we are able to characterize and compare certain biochemical and biophysical properties of (+) sc, (-) sc, and relaxed (rx) DNA molecules using different techniques, such as UV melting, circular dichroism, and fluorescence spectrometry. Our results show that (+) sc, (-) sc, and rx DNA templates can only be partially melted due to the fact that these DNA templates are closed circular DNA molecules and the two DNA strands cannot be completely separated upon denaturation at high temperatures. We also find that the fluorescence intensity of a DNA-binding dye SYTO12 upon binding to the (-) sc DNA is significantly higher than that of its binding to the (+) sc DNA. This unique property may be used to differentiate the (-) sc DNA from the (+) sc DNA. Additionally, we demonstrate that E. coli topoisomerase I cannot relax the (+) sc DNA. In contrast, E. coli DNA gyrase can efficiently convert the (+) sc DNA to the (-) sc DNA. Furthermore, our dialysis competition assays show that DNA intercalators prefer binding to the (-) sc DNA