Abstract
To detect partially condensed conformations of a double-stranded DNA molecule, single molecule fluorescence microscopy is performed here. The single DNA molecules are ethidium stained, 670 kilobase pair bacteriophage G genomes that are observed both during and after expulsion from capsids. Expulsion occurs in an agarose gel. Just after expulsion, the entire G DNA molecule typically has a partially condensed conformation not previously described (called a balloon). A balloon subsequently extrudes a filamentous segment of DNA. The filamentous segment becomes gently elongated via diffusion into the network that forms the agarose gel. The elongated DNA molecule usually has bright spots that undergo both appearance/disappearance and apparent motion. These spots are called dynamic spots. A dynamic spot is assumed to be the image of a zone of partially condensed DNA segments (globule). The positions of globules along an elongated DNA molecule 1) are restricted primarily to time-stable regions with comparatively high thermal motion-induced, micrometer-scale bending of the DNA molecule and 2) move within a given region on a time scale smaller than the time scale of recording. Less mobile globules are observed when either magnesium cation or ethanol is added before gel-embedding DNA molecules. These observations are explained by globules induced at equilibrium by a bending-dependent, inter-DNA segment force. Theory has previously predicted that globules are induced by electrostatic forces along an electrically charged polymer at equilibrium. The hypothesis is proposed that intracellular DNA globules assist action-at-a-distance during DNA metabolism.