Jonathan M. Fogg scite author profile

By regulating access to the genetic code, DNA supercoiling strongly affects DNA metabolism. Despite its importance, however, much about supercoiled DNA (positively supercoiled DNA, in particular) remains unknown. Here we use electron cryo-tomography together with biochemical analyses to investigate structures of individual purified DNA minicircle topoisomers with defined degrees of supercoiling. Our results reveal that each topoisomer, negative or positive, adopts a unique and surprisingly wide distribution of three-dimensional conformations. Moreover, we uncover striking differences in how the topoisomers handle torsional stress. As negative supercoiling increases, bases are increasingly exposed. Beyond a sharp supercoiling threshold, we also detect exposed bases in positively supercoiled DNA. Molecular dynamics simulations independently confirm the conformational heterogeneity and provide atomistic insight into the flexibility of supercoiled DNA. Our integrated approach reveals the three-dimensional structures of DNA that are essential for its function.

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Exploring writhe in supercoiled minicircle DNA

Fogg

Kolmakova

Rees

et al. 2006

J. Phys.: Condens. Matter

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Using λ-Int recombination in E. coli, we have generated milligram quantities of supercoiled minicircle DNA. Intramolecular Int recombination was efficient down to lengths ~254 bp. When nicked and religated in the presence of ethidium bromide, 339 bp minicircles adopted at least seven unique topoisomers that presumably correspond to ΔLk ranging from 0 to −6, which we purified individually. We used these minicircles, with unique ΔLk, to address the partition into twist and writhe as a function of ΔLk. Gel electrophoresis and atomic force microscopy revealed progressively higher writhe conformations in the presence of 10 mM CaCl 2 or MgCl 2 . From simplistic calculations of the bending and twisting energies, we predict the elastic free energy of supercoiling for these minicircles to be lower than if the supercoiling was partitioned mainly into twist. The predicted writhe corresponds closely with that which we observed experimentally in the presence of divalent metal ions. However, in the absence of divalent metal ions only limited writhe was observed, demonstrating the importance of electrostatic effects on DNA structure, when the screening of charges on the DNA is weak. This study represents a unique insight into the supercoiling of minicircle DNA, with implications for DNA structure in general.

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Simultaneous DNA Binding and Bending by EcoRV Endonuclease Observed by Real-Time Fluorescence

et al. 2003

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The complete catalytic cycle of EcoRV endonuclease has been observed by combining fluorescence anisotropy with fluorescence resonance energy transfer (FRET) measurements. Binding, bending, and cleavage of substrate oligonucleotides were monitored in real time by rhodamine-x anisotropy and by FRET between rhodamine and fluorescein dyes attached to opposite ends of a 14-mer DNA duplex. For the cognate GATATC site binding and bending are found to be nearly simultaneous, with association and bending rate constants of (1.45-1.6) x 10(8) M(-1) s(-1). On the basis of the measurement of k(off) by a substrate-trapping approach, the equilibrium dissociation constant of the enzyme-DNA complex in the presence of inhibitory calcium ions was calculated as 3.7 x 10(-12) M from the kinetic constants. Further, the entire DNA cleavage reaction can be observed in the presence of catalytic Mg(2+) ions. These measurements reveal that the binding and bending steps occur at equivalent rates in the presence of either Mg(2+) or Ca(2+), while a slow decrease in fluorescence intensity following bending corresponds to k(cat), which is limited by the cleavage and product dissociation steps. Measurement of k(on) and k(off) in the absence of divalent metals shows that the DNA binding affinity is decreased by 5000-fold to 1.4 x 10(-8) M, and no bending could be detected in this case. Together with crystallographic studies, these data suggest a model for the induced-fit conformational change in which the role of divalent metal ions is to stabilize the sharply bent DNA in an orientation suitable for accessing the catalytic transition state.

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Bullied no more: when and how DNA shoves proteins around

Fogg

Randall

Pettitt

et al. 2012

Quart. Rev. Biophys.

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The predominant protein-centric perspective in protein–DNA-binding studies assumes that the protein drives the interaction. Research focuses on protein structural motifs, electrostatic surfaces and contact potentials, while DNA is often ignored as a passive polymer to be manipulated. Recent studies of DNA topology, the supercoiling, knotting, and linking of the helices, have shown that DNA has the capability to be an active participant in its transactions. DNA topology-induced structural and geometric changes can drive, or at least strongly influence, the interactions between protein and DNA. Deformations of the B-form structure arise from both the considerable elastic energy arising from supercoiling and from the electrostatic energy. Here, we discuss how these energies are harnessed for topology-driven, sequence-specific deformations that can allow DNA to direct its own metabolism.

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Jonathan M. Fogg

Structural diversity of supercoiled DNA

Exploring writhe in supercoiled minicircle DNA

Simultaneous DNA Binding and Bending by EcoRV Endonuclease Observed by Real-Time Fluorescence

Bullied no more: when and how DNA shoves proteins around

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