HU promotes higher-order chromosome organisation and influences DNA replication rates in Streptococcus pneumoniae

Nucleoid-associated proteins (NAPs) are crucial for maintaining chromosomal compaction and architecture and are actively involved in DNA replication, recombination, repair, and gene regulation. In the opportunistic pathogen Streptococcus pneumoniae, HU is the only identified NAP, and its role in chromosome conformation and other essential processes has not yet been investigated. Here, we use a multi-scale approach to explore the role of HU in chromosome conformation and segregation dynamics. By combining superresolution microscopy and whole-genome binding analysis, we describe the nucleoid as a dynamic structure where HU binds transiently across the entire nucleoid, with a preference for the origin of replication over the terminus. Reducing cellular HU levels impacts nucleoid maintenance and disrupts robust nucleoid scaling with cell size. This effect is similar to the distortion caused by fluoroquinolone-antibiotics, supporting earlier observations that HU is essential for maintaining DNA supercoiling. Furthermore, in cells lacking HU, the replication machinery is misplaced, and cells are unable to initiate and proceed with on-going replication. Chromosome conformation capture (Hi-C) experiments revealed that HU is required to maintain cohesion between the two chromosomal arms, in a similar way to the structural maintenance of the chromosome complex SMC. Together, we show that by promoting long-range chromosome interactions and supporting the architecture of the domain encompassing the origin, HU is fundamental for chromosome integrity and the intimately related processes of chromosome replication and segregation.