Facilitated Dissociation of Nucleoid Associated Proteins from DNA in the Bacterial Confinement

Abstract

Transcription machinery depends on the temporal formation of protein-DNA complexes. Recent experiments demonstrated that lifetime of the complex can also affect transcription. In parallel, in vitro single-molecule studies showed that nucleoid-associated proteins (NAPs) leave the DNA rapidly as the bulk concentration of the protein increases via facilitated dissociation (FD). Never-theless, whether such concentration-dependent mechanism is functional in a bacterial cell, in which NAP levels and the 3D chromosomal structure are often coupled, is not clear a priori. Here, by using extensive coarse-grained molecular simulations, we model the unbinding of specific and nonspecific dimeric NAPs from a high-molecular-weight circular DNA molecule in a cylindrical structure mimicking the cellular confinement of a bacterial chromosome. Our simulations show that physiologically relevant peak protein levels (tens of micromolar) lead to highly compact chromosomal structures. This compaction results in rapid off rates (shorter DNA-residence times) but only for specifically DNA-binding NAPs such as the factor for inversion stimulation (Fis). Contrarily, for nonspecific NAPs, the off rates decrease as the protein levels increase, suggesting an inverse FD pattern. The simulations with restrained chromosome models reveal that this inverse response is due to DNA-segmental fluctuations, and that chromosomal compaction is in favor of faster protein dissociation. Overall, our results indicate that cellular-concentration level of a structural DNA-binding protein can be highly intermingled with its DNA-residence time.