Conformational transition of giant DNA in a confined space surrounded by a phospholipid membrane.

It has been established that a long DNA molecule exhibits a large discrete conformational change from a coiled state to a highly folded state in aqueous solution, depending on the presence of various condensing agents such as polyamines. In this study, T4 DNA labeled with fluorescent dyes was encapsulated in a cell-sized microdroplet covered with a phospholipid membrane to investigate the conformational behavior of a DNA molecule in such a confined space. Fluorescence microscopy showed that the presence of Mg(2+) induced the adsorption of DNA onto the membrane inner-surface of a droplet composed of phosphatidylethanolamine, while no adsorption was observed onto a phosphatidylcholine membrane.

In situ analysis of the higher-order genome structure in a single Escherichia coli cell.

We developed a novel method for the in situ analysis of the higher-order structure of an individual genome from a single Escherichia coli cell using laser tweezers. Initially, condensed DNA was stably grasped by a laser without any chemical modification and without physical attachment to an artificial object such as micro-plastic beads. Under optical transport, the trapped genome gradually unfolded in solution due to viscous friction.