Abstract
Large DNA molecules are a promising platform for in vitro single-molecule biochemical analysis to investigate DNA-protein interactions by fluorescence microscopy. For many studies, intercalating fluorescent dyes have been primary DNA staining reagents, but they often cause photo-induced DNA breakage as well as structural deformation. As a solution, we previously developed several fluorescent-protein DNA-binding peptides or proteins (FP-DBP) for reversibly staining DNA molecules without structural deformation or photo-induced damage. However, they cannot stain DNA in a condition similar to a physiological salt concentration that most biochemical reactions require. Given these concerns, here we developed a salt-tolerant FP-DBP: truncated transcription activator-like effector (tTALE-FP), which can stain DNA up to 100 mM NaCl. Moreover, we found an interesting phenomenon that the tTALE-FP stained DNA evenly in 1 × TE buffer but showed AT-rich specific patterns from 40 mM to 100 mM NaCl. Using an assay based on fluorescence resonance energy transfer, we demonstrated that this binding pattern is caused by a higher DNA binding affinity of tTALE-FP for AT-rich compared to GC-rich regions. Finally, we used tTALE-FP in a single molecule fluorescence assay to monitor real-time restriction enzyme digestion of single DNA molecules. Altogether, our results demonstrate that this protein can provide a useful alternative as a DNA stain over intercalators.
Highlights
Large DNA molecules have been a versatile platform to investigate a variety of genomic, epigenetic, biochemical, and biophysical studies[1]
We have previously reported the development of FP-tagged DNA-binding peptides (FP-DBPs) as new staining reagents[25,34,35,36]
We noticed that transcription activator-like effector (TALE)-FP and to a nuclease domain (TALEN) are capable of binding DNA within a cell nucleus that generally contains relatively high-salt concentrations
Summary
Large DNA molecules have been a versatile platform to investigate a variety of genomic, epigenetic, biochemical, and biophysical studies[1]. We demonstrated the power of the tTALE-FP for the visualization of real-time restriction enzyme digestion reactions on single-molecule DNA by comparing it with the YOYO-1 stained DNA molecule.
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