Abstract
ABSTRACT Dps is the most abundant nucleoid-associated protein in starved Escherichia coli with ∼180,000 copies per cell. Dps binds DNA and oxidises iron, facilitating survival in harsh environments. Dps-DNA complexes can form crystalline structures, leading to the proposed model that Dps reorganises the starved E. coli nucleoid into a compact liquid crystal, slowing chromosome dynamics and limiting access of other proteins to DNA. In this work, we directly tested this model using live-cell super-resolution microscopy and Hi-C analysis. We found that after 96 h of starvation, Dps compacts the nucleoid and increases short-range DNA-DNA interactions, but does not affect chromosome accessibility to large protein nanocages or small restriction enzymes. We also report that chromosome dynamics and organisation are primarily impacted by the bacterial growth phase; the effect of Dps is relatively minor. Our work clarifies the role of Dps in modulating nucleoid properties, and we propose an updated model for Dps-DNA interactions in which Dps binds, protects and compacts DNA largely without influencing chromosome access, dynamics and organisation. Additionally, this work provides a general framework for assessing the impact of nucleoid-associated proteins on key aspects of chromosome function in live cells. TOC
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ABSTRACT
Dps is the most abundant nucleoid-associated protein in starved Escherichia coli with ∼180,000 copies per cell. Dps binds DNA and oxidises iron, facilitating survival in harsh environments. Dps-DNA complexes can form crystalline structures, leading to the proposed model that Dps reorganises the starved E. coli nucleoid into a compact liquid crystal, slowing chromosome dynamics and limiting access of other proteins to DNA. In this work, we directly tested this model using live-cell super-resolution microscopy and Hi-C analysis. We found that after 96 h of starvation, Dps compacts the nucleoid and increases short-range DNA-DNA interactions, but does not affect chromosome accessibility to large protein nanocages or small restriction enzymes. We also report that chromosome dynamics and organisation are primarily impacted by the bacterial growth phase; the effect of Dps is relatively minor. Our work clarifies the role of Dps in modulating nucleoid properties, and we propose an updated model for Dps-DNA interactions in which Dps binds, protects and compacts DNA largely without influencing chromosome access, dynamics and organisation. Additionally, this work provides a general framework for assessing the impact of nucleoid-associated proteins on key aspects of chromosome function in live cells.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
We have modified the manuscript with text and figure edits for clarity and new analysis (Figures 4, S5, S8, S10, and S11; Table S5).
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