Theory for Spin−Lattice Relaxation of Spin Probes on Weakly Deformable DNA

Smith, Alyssa L.; Čekan, Pavol; Rangel, David P.; Sigurdsson, Snorri Th.; Mailer, Colin; Robinson, Bruce H.

doi:10.1021/jp7111704

Cited by 6 publications

(15 citation statements)

References 70 publications

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“…Nucleic acid duplexes of moderate length are rigid elements with defined, regular shapes so that dynamic properties can be predicted and compared to experimental measures 21,40. We therefore determined the FPA of 6-MI-labeled DNA duplexes of varying length and compared the experimental values to predicted values (see Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

Probing the Dynamics of the P1 Helix within the Tetrahymena Group I Intron

et al. 2009

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RNA conformational transformations are integral to RNA's biological functions. Further, structured RNA molecules exist as a series of dynamic intermediates in the course of folding or complexation with proteins. Thus, an understanding of RNA folding and function will require deep and incisive understanding of its dynamic behavior. However, existing tools to investigate RNA dynamics are limited. Here we introduce a powerful fluorescence polarization anisotropy approach that utilizes a rare base analog that retains substantial fluorescence when incorporated into helices. We show that 6-methylisoxanthopterin (6-MI) can be used to follow the nanosecond dynamics of individual helices. We then use 6-MI to probe the dynamics of an individual helix, referred to as P1, within the 400nt Tetrahymena group I ribozyme. Comparisons of the dynamics of the P1 helix in wild type and mutant ribozymes and in model constructs reveal a highly immobilized docked state of the P1 helix, as expected, and a relatively mobile ‘open complex’ or undocked state. This latter result rules out a model in which slow docking of the P1 helix into its cognate tertiary interactions arises from a stable alternatively docked conformer. The results are consistent with a model in which stacking and tertiary interactions of the A3 tether connecting the P1 helix to the body of the ribozyme limit P1 mobility and slow its docking, and this model is supported by cross-linking results. The ability to isolate the nanosecond motions of individual helices within complex RNAs and RNA/protein complexes will be valuable in distinguishing between functional models and in discerning the fundamental behavior of important biological species.

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Section: Resultsmentioning

confidence: 99%

Probing the Dynamics of the P1 Helix within the Tetrahymena Group I Intron

et al. 2009

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“…The dashed black line indicates a different linear correlation between spectral width and R 1e for the bulged samples. The R 1 e values, calculated on the basis of a rigid 14-mer,39,53 demonstrate that the experimental R 1 e values are about twice as large as the calculated values. The increased rate of experimental values arises from the internal motion of the spin probe over and above that of a rigid object 39.…”

Section: Resultsmentioning

confidence: 68%

“…The R 1 e values, calculated on the basis of a rigid 14-mer,39,53 demonstrate that the experimental R 1 e values are about twice as large as the calculated values. The increased rate of experimental values arises from the internal motion of the spin probe over and above that of a rigid object 39. The R 1e , like the spectral width

(2 〈 A_{italiczz} 〉)

, indicates Ç/C has the least mobility of the Ç/X samples.…”

Section: Resultsmentioning

confidence: 68%

“…As a general principle,

2 〈 A_{italiczz} 〉

is determined in main part by dynamics processes that have rotational diffusion coefficients comparable to the width of the spectrum, which is on the order of 10 8 Hz . In contrast, the R 1 e is dominated by dynamics process that compete with the spectrometer frequency, which is 9.10 9 Hz (for X band spectrometers) 39,53,55. Therefore, the results from the simulated spectra (Figure 6 (top) , blue line) demonstrates that R 1 e for a sample with no internal motion does not depend strongly on the uniform mode of motion of the spin label, as the uniform mode for a ~14-mer is much slower than the spectrometer frequency.…”

Section: Discussionmentioning

confidence: 98%

“…The three parameters are 1 ) the full spectral splitting, called

2 〈 A_{italiczz} 〉

, 2 ) the central linewidth, which is directly related to the mobility parameter of Hubbell,38 and 3 ) the spin lattice relaxation rate, R 1 e 39. Each parameter depends on the dynamics in different ways.…”

Section: Discussionmentioning

confidence: 99%

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Conformational Equilibria of Bulged Sites in Duplex DNA Studied by EPR Spectroscopy

et al. 2009

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Conformational flexibility in nucleic acids provides a basis for complex structures, binding, and signaling. One-base bulges directly neighboring single-base mismatches in nucleic acids can be present in a minimum of two distinct conformations, complicating the examination of the thermodynamics by calorimetry or UV-monitored melting techniques. To provide additional information about such structures, we demonstrate how electron paramagnetic resonance (EPR) active spin-labeled base analogues, base-specifically incorporated into the DNA, are monitors of the superposition of different bulge-mismatch conformations. EPR spectra provide information about the dynamic environments of the probe. This information is cast in terms of "dynamic signatures" that have an underlying basis in structural variations. By examining the changes in the equilibrium of the different states across a range of temperatures, the enthalpy and entropy of the interconversion among possible conformations can be determined. The DNA constructs with a single bulge neighboring a single-base mismatch ("bulge-mismatches") may be approximately modeled as an equilibrium between two possible conformations. This structural information provides insight into the local composition of the bulge-mismatch sequences. Experiments on the bulge-mismatches show that basepairing across the helix can be understood in terms of purine and pyrimidine interactions, rather than specific bases. Measurements of the enthalpy and entropy of formation for the bulgemismatches by differential scanning calorimetry and UV-monitored melting confirm that the formation of bulge-mismatches is in fact more complicated than a simple two-state process, consistent with the base-specific spectral data that bulge-mismatches exist in multiple conformations in the pre-melting temperature region. We find that the calculations with the nearest-neighbor (NN) model for the two likely conformations do not correlate well with the populations of structures and thermodynamic parameters inferred from the base-specific EPR dynamics probe. We report that the base-specific spin probes are able to identify a bi-stable, temperature dependent, switching between conformations for a particular complex bulged construct.* To whom correspondence should be addressed: Phone: (206) 543-1773, FAX: (206) 616-6250, email: robinson@chem.washington.edu SUPPORTING INFORMATION AVAILABLE:Figures illustrating: two-component fit of EPR spectra; calculation of α from UV melting curves; rigid 14-mer simulated, FAST, and SLOW spectra at 0, 20, and 40 °C; results of fitting spectra to FAST and "closest match Ç/X" spectra; NN calculation comparisons; spectra and analysis of doubly spin-labeled samples for distance measurements. This material is available free of charge via the Internet at

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Preparation, resonance assignment, and preliminary dynamics characterization of residue specific 13C/15N-labeled elongated DNA for the study of sequence-directed dynamics by NMR

Nikolova

Al‐Hashimi

2009

J Biomol NMR

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DNA is a highly flexible molecule that undergoes functionally important structural transitions in response to external cellular stimuli. Atomic level spin relaxation NMR studies of DNA dynamics have been limited to short duplexes in which sensitivity to biologically relevant fluctuations occurring at nanosecond timescales is often inadequate. Here, we introduce a method for preparing residue-specific (13)C/(15)N-labeled elongated DNA along with a strategy for establishing resonance assignments and apply the approach to probe fast inter-helical bending motions induced by an adenine tract. Preliminary results suggest the presence of elevated A-tract independent end-fraying internal motions occurring at nanosecond timescales, which evade detection in short DNA constructs and that penetrate deep (7 bp) within the DNA helix and gradually fade away towards the helix interior.

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Theory for Spin−Lattice Relaxation of Spin Probes on Weakly Deformable DNA

Cited by 6 publications

References 70 publications

Probing the Dynamics of the P1 Helix within the Tetrahymena Group I Intron

Probing the Dynamics of the P1 Helix within the Tetrahymena Group I Intron

Conformational Equilibria of Bulged Sites in Duplex DNA Studied by EPR Spectroscopy

Preparation, resonance assignment, and preliminary dynamics characterization of residue specific 13C/15N-labeled elongated DNA for the study of sequence-directed dynamics by NMR

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