Abstract
Chromosome structure and function is studied in cells using imaging and chromosome-conformation-based methods as well as in vitro with a range of single-molecule techniques. Here we present a method to obtain genome-size (megabasepair length) deproteinated DNA for in vitro studies, which provides DNA substrates that are two orders of magnitude longer than typically studied in single-molecule experiments. We isolated chromosomes from bacterial cells and enzymatically digested the native proteins. Mass spectrometry indicated that 97-100% of DNA-binding proteins are removed from the sample. Upon protein removal, we observed an increase in the radius of gyration of the DNA polymers, while quantification of the fluorescence intensities showed that the length of the DNA objects remained megabasepair sized. In first proof-of-concept experiments using these deproteinated long DNA molecules, we observed DNA compaction upon adding the DNA-binding protein Fis or PEG crowding agents and showed that it is possible to track the motion of a fluorescently labelled DNA locus. These results indicate the practical feasibility of a ‘genome-in-a-box’ approach to study chromosome organization from the bottom up.
Competing Interest Statement
The authors have declared no competing interest.