Abstract

HU is a protein that plays a role in various bacterial processes including compaction, transcription and replication of the genome. Here, we use atomic force microscopy to study the effect of HU on the stiffness and supercoiling of double-stranded DNA. First, we measured the persistence length, height profile, contour length and bending angle distribution of the DNA–HU complex after different incubation times of HU with linear DNA. We found that the persistence and contour length depend on the incubation time. At high concentrations of HU, DNA molecules first become stiff with a larger value of the persistence length. The persistence length then decreases over time and the molecules regain the flexibility of bare DNA after ∼2 h. Concurrently, the contour length shows a slight increase. Second, we measured the change in topology of closed circular relaxed DNA following binding of HU. Here, we observed that HU induces supercoiling over a similar time span as the measured change in persistence length. Our observations can be rationalized in terms of the formation of a nucleoprotein filament followed by a structural rearrangement of the bound HU on DNA. The rearrangement results in a change in topology, an increase in bending flexibility and an increase in contour length through a decrease in helical pitch of the duplex.

Highlights

  • The chromosome of most bacteria consists of a single closed circular DNA molecule of considerable size

  • Bacterial chromosomal DNA is about a thousand times compacted and occupies $25% of the cellular volume [1,2]. This compaction is facilitated by negative supercoiling with the help of enzymes such as topoisomerase and gyrase, but nucleoid associated proteins (NAPs), macromolecular crowding and confinement by the cell envelope are thought to play a role [3,4,5,6]

  • We obtain a sufficient number of individual DNA molecules in a single frame for good statistics on the persistence length measurements

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Summary

Introduction

The chromosome of most bacteria consists of a single closed circular DNA molecule of considerable size. Various single-molecule experiments have shown that the persistence length depends on the concentration of HU.

Results
Conclusion

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