Bacterial chromosome organization II: few special cross-links, cell confinement, and molecular crowders play the pivotal roles

Abstract

Using a bead-spring model of bacterial DNA polymers of C. crescentus and E. coli we show that just 33 and 38 effective cross-links at special positions along the chain contour of the DNA can lead to the large-scale organization of the DNA polymer, where confinement effects of the cell walls play a key role in the organization. The positions of the 33 cross-links along the chain contour are chosen from the contact map data of C. crescentus. We represent 1000 base pairs as a coarse-grained monomer in our bead-spring flexible ring polymer model of the DNA. Thus a 4017 beads on a flexible ring polymer represents the C. crescentus DNA with 4017 kilo-base pairs. Choosing suitable parameters from our preceding study, we also incorporate the role of molecular crowders and the ability of the chain to release topological constraints. We validate our prediction of the organization of the C. crescentus with available experimental contact map data and also give a prediction of the approximate positions of different segments within the cell in 3D. For the E. coli chromosome with 4.6 million base pairs, we need around 38 effective cross-links with cylindrical confinement to organize the chromosome. We also predict the 3D organization of the E. coli chromosome segments within the cylinder which represents the cell wall.