Maarten C. Noom scite author profile

Both prokaryotic and eukaryotic organisms contain DNA bridging proteins, which can have regulatory or architectural functions. The molecular and mechanical details of such proteins are hard to obtain, in particular if they involve non-specific interactions. The bacterial nucleoid consists of hundreds of DNA loops, shaped in part by non-specific DNA bridging proteins such as histone-like nucleoid structuring protein (H-NS), leucine-responsive regulatory protein (Lrp) and SMC (structural maintenance of chromosomes) proteins. We have developed an optical tweezers instrument that can independently handle two DNA molecules, which allows the systematic investigation of protein-mediated DNA-DNA interactions. Here we use this technique to investigate the abundant non-specific nucleoid-associated protein H-NS, and show that H-NS is dynamically organized between two DNA molecules in register with their helical pitch. Our optical tweezers also allow us to carry out dynamic force spectroscopy on non-specific DNA binding proteins and thereby to determine an energy landscape for the H-NS-DNA interaction. Our results explain how the bacterial nucleoid can be effectively compacted and organized, but be dynamic in nature and accessible to DNA-tracking motor enzymes. Finally, our experimental approach is widely applicable to other DNA bridging proteins, as well as to complex DNA interactions involving multiple DNA molecules.

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The architectural role of nucleoid-associated proteins in the organization of bacterial chromatin: A molecular perspective

Luijsterburg

Noom

Wuite

et al. 2006

Journal of Structural Biology

247

251

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Alba shapes the archaeal genome using a delicate balance of bridging and stiffening the DNA

et al. 2012

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Architectural proteins have an important role in shaping the genome and act as global regulators of gene expression. How these proteins jointly modulate genome plasticity is largely unknown. In archaea, one of the most abundant proteins, Alba, is considered to have a key role in organizing the genome. Here we characterize the multimodal architectural properties and interplay of the Alba1 and Alba2 proteins using single-molecule imaging and manipulation techniques. We demonstrate that the two paralogues can bridge and rigidify DNA and that the interplay between the two proteins influences the balance between these effects. Our data yield a structural model that explains the multimodal behaviour of Alba proteins and its impact on genome folding.

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Visualizing single DNA-bound proteins using DNA as a scanning probe

et al. 2007

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Many biological processes involve enzymes moving along DNA. Such motion might be impeded by DNA-bound proteins or DNA supercoils. Current techniques are incapable of directly measuring forces that such 'roadblocks' might impose. We constructed a setup with four independently moveable optical traps, allowing us to manipulate two DNA molecules held between beads. By tightly wrapping one DNA around the other, we created a probe that can be scanned along the contour of the second DNA. We found that friction between the two polymers remains below 1 pN. Upon encountering DNA-bound proteins substantial friction forces are measured, allowing accurate localization of protein positions. Furthermore, these proteins remained associated at low probe tensions but could be driven off using forces greater than 20 pN. Finally, the full control of the orientation of two DNA molecules opens a wide range of experiments on proteins interacting with multiple DNA regions.

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Visualizing the Formation and Collapse of DNA Toroids

Broek¹,

Noom²,

Mameren³

et al. 2010

Biophysical Journal

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In living organisms, DNA is generally confined into very small volumes. In most viruses, positively charged multivalent ions assist the condensation of DNA into tightly packed toroidal structures. Interestingly, such cations can also induce the spontaneous formation of DNA toroids in vitro. To resolve the condensation dynamics and stability of DNA toroids, we use a combination of optical tweezers and fluorescence imaging to visualize in real-time spermine-induced (de)condensation in single DNA molecules. By actively controlling the DNA extension, we are able to follow (de)condensation under tension with high temporal and spatial resolution. We show that both processes occur in a quantized manner, caused by individual DNA loops added onto or removed from a toroidal condensate that is much smaller than previously observed in similar experiments. Finally, we present an analytical model that qualitatively captures the experimentally observed features, including an apparent force plateau.

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Maarten C. Noom

Bacterial chromatin organization by H-NS protein unravelled using dual DNA manipulation

The architectural role of nucleoid-associated proteins in the organization of bacterial chromatin: A molecular perspective

Alba shapes the archaeal genome using a delicate balance of bridging and stiffening the DNA

Visualizing single DNA-bound proteins using DNA as a scanning probe

Visualizing the Formation and Collapse of DNA Toroids

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