Site-directed Spin Labeling Studies on Nucleic Acid Structure and Dynamics

A model system for investigating lineshape/structure correlations in RNA site-directed spin labeling

The GNRA (N: any nucleotide; R: purine) tetraloop/receptor interaction is believed to be one of the most frequently occurring tertiary interaction motifs in RNAs, but an isolated tetraloop/receptor complex has not been identified in solution. In the present work, site-directed spin labeling is applied to detect tetraloop/receptor complex formation and estimate the free energy of interaction. For this purpose, the GAAA tetraloop/receptor interaction was chosen as a model system. A method was developed to place nitroxide labels at specific backbone locations in an RNA hairpin containing the GAAA tetraloop. Formation of the tetraloop/receptor complex was monitored through changes in the rotational correlation time of the tetraloop and the attached nitroxide. Results show that a hairpin containing the GAAA tetraloop forms a complex with an RNA containing the 11-nucleotide GAAA tetraloop receptor motif with an apparent Kd that is strongly dependent on Mg2+. At 125 mM MgCl2, Kd = 0.40 +/- 0.05 mM. The corresponding standard free energy of complex formation is -4.6 kcal/mol, representing the energetics of the tetraloop/receptor interaction in the absence of other tertiary constraints. The experimental strategy presented here should have broad utility in quantifying weak interactions that would otherwise be undetectable, for both nucleic acids and nucleic acid-protein complexes.

Site-directed spin labeling (SDSL) is widely applied for structural studies of biopolymers by electron paramagnetic resonance (EPR). However, SDSL of long RNA sequences still remains a challenging task. Here, we propose a novel SDSL approach potentially suitable for long natural RNAs, which is based on the attachment of a linker containing an aliphatic amino group to the target nucleotide residue followed by selective coupling of a spin label to this amino group. Such a linker can be attached to the desired RNA residue via a sequence-specific reaction with the derivatives of oligodeoxyribonucleotides. To verify this approach, we applied it to model RNA duplex with known structure and expected distance between corresponding residues. A new 2,5-bis(spirocyclohexane)-substituted spin label with advanced stability and relaxation properties has been used, and the distance distribution measured using Q-band (34 GHz) pulsed double electron-electron resonance corresponds well to the expected one. We have additionally validated the obtained results by studying a similar RNA duplex, where the linker with the aliphatic amino group was introduced via solid-phase synthesis. Although this novel SDSL approach does not provide an advantage in precision of molecular distance measurements, we believe that its applicability to long RNAs is a crucial benefit for future structural studies using pulse EPR.

Site directed spin labeling studies of structure and dynamics in bacteriorhodopsin

Site directed spin labeling studies of Escherichia coli dihydroorotate dehydrogenase N-terminal extension

Structure of the cdb3-ankD34 Complex from Site Directed Spin Labeling Studies

In site-directed spin labeling (SDSL), local structural and dynamic information is obtained via electron paramagnetic resonance (EPR) spectroscopy of a stable nitroxide radical attached site-specifically to a macromolecule. Analysis of electron spin dipolar interactions between pairs of nitroxides yields the inter-nitroxide distance, which provides quantitative structural information. The development of pulse EPR methods has enabled such distance measurements up to 70 Å in bio-molecules, thus opening up the possibility of SDSL global structural mapping. This study evaluates SDSL distance measurement using a nitroxide (designated as R5) that can be attached, in an efficient and cost-effective manner, to a phosphorothioate backbone position at arbitrary DNA or RNA sequences. R5 pairs were attached to selected positions of a dodecamer DNA duplex with a known NMR structure, and eight distances, ranging from 20 to 40 Å, were measured using double electron-electron resonance (DEER). The measured distances correlated strongly (R2 = 0.98) with the predicted values calculated based on a search of sterically allowable R5 conformations in the NMR structure, thus demonstrating accurate distance measurements using R5. Furthermore, distance measurement in a 42 kD DNA was demonstrated. The results establish R5 as a sequence-independent probe for global structural mapping of DNA and DNA–protein complexes.

Site-directed spin labeling (SDSL) has been invaluable in the analysis of protein structure and dynamics, and has been particularly useful in the study of membrane proteins. ExoU, an important virulence factor in Pseudomonas aeruginosa infections, is a bacterial phospholipase A2 that functions at the membrane - aqueous interface. Using SDSL methodology developed in the Hubbell lab, we find that the region surrounding the catalytic site of ExoU is buried within the tertiary structure of the protein in the soluble, apoenzyme state, but shows a significant increase in dynamics upon membrane binding and activation by ubiquitin. Continuous wave (CW) power saturation EPR studies show that the conserved serine hydrolase motif of ExoU localizes to the membrane surface in the active, holoenzyme state. SDSL studies on the C-terminal four-helix bundle (4HB) domain of ExoU similarly show a co-operative effect of ubiquitin binding and membrane association. CW power saturation studies of the 4HB domain indicate that two interhelical loops intercalate into the lipid bilayer upon formation of the holoenzyme state, anchoring ExoU at the membrane surface. Together these studies establish the orientation and localization of ExoU and the membrane surface, and illustrate the power of SDSL as applied to peripheral membrane proteins.

The technique of site-directed spin labeling (SDSL) provides information on bio-molecular systems by monitoring the behaviors of a stable radical tag (i.e., spin label) using electron paramagnetic resonance (EPR) spectroscopy. SDSL studies of nucleic acids and protein–nucleic acid complexes have yielded unique information that is difficult to derive from other methods. In this chapter, we describe strategies used in nucleic acid SDSL investigations, and summarize advancements with a focus on those reported during the past five years.

BackgroundSpin labels, which are chemically stable radicals attached at specific sites of a bio-molecule, enable investigations on structure and dynamics of proteins and nucleic acids using techniques such as site-directed spin labeling and paramagnetic NMR. Among spin labels developed, the class of rigid labels have limited or no independent motions between the radical bearing moiety and the target, and afford a number of advantages in measuring distances and monitoring local dynamics within the parent bio-molecule. However, a general method for attaching a rigid label to nucleic acids in a nucleotide-independent manner has not been reported.ResultsWe developed an approach for installing a nearly rigid nitroxide spin label, designated as R5c, at a specific site of the nucleic acid backbone in a nucleotide-independent manner. The method uses a post-synthesis approach to covalently attach the nitroxide moiety in a cyclic fashion to phosphorothioate groups introduced at two consecutive nucleotides of the target strand. R5c-labeled nucleic acids are capable of pairing with their respective complementary strands, and the cyclic nature of R5c attachment significantly reduced independence motions of the label with respect to the parent duplex, although it may cause distortion of the local environment at the site of labeling. R5c yields enhanced sensitivity to the collective motions of the duplex, as demonstrated by its capability to reveal changes in collective motions of the substrate recognition duplex of the 120-kDa Tetrahymena group I ribozyme, which elude detection by a flexible label.ConclusionsThe cyclic R5c nitroxide can be efficiently attached to a target nucleic acid site using a post-synthetic coupling approach conducted under mild biochemical conditions, and serves as a viable label for experimental investigation of segmental motions in nucleic acids, including large folded RNAs.Electronic supplementary materialThe online version of this article (doi:10.1186/s13628-015-0019-5) contains supplementary material, which is available to authorized users.

It has been postulated that the hydrophobic loop of actin (residues 262-274) swings out and inserts into the opposite strand in the filament, stabilizing the filament structure. Here, we analyzed the hydrophobic loop dynamics utilizing four mutants that have cysteine residues introduced at a single location along the yeast actin loop. Lateral, copper-catalyzed disulfide cross-linking of the mutant cysteine residues to the native C374 in the neighboring strand within the filament was fastest for S265C, followed by V266C, L267C, and then L269C. Site-directed spin labeling (SDSL) studies revealed that C265 lies closest to C374 within the filament, followed by C266, C267, and then C269. These results are not predicted by the Holmes extended loop model of F-actin. Furthermore, we find that disulfide cross-linking destroys L267C and L269C filaments; only small filaments are observed via electron microscopy. Conversely, phalloidin protects the L267C and L269C filaments and inhibits their disulfide cross-linking. Combined, our data indicate that, in solution, the loop resides predominantly in a "parked" position within the filament but is able to dynamically populate other conformational states which stabilize or destabilize the filament. Such states may be exploited within a cell by filament-stabilizing and -destabilizing factors.

Aβ42 oligomers play key roles in the pathogenesis of Alzheimer disease, but their structures remain elusive partly due to their transient nature. Here, we show that Aβ42 in a fusion construct can be trapped in a stable oligomer state, which recapitulates characteristics of prefibrillar Aβ42 oligomers and enables us to establish their detailed structures. Site-directed spin labeling and electron paramagnetic resonance studies provide structural restraints in terms of side chain mobility and intermolecular distances at all 42 residue positions. Using these restraints and other biophysical data, we present a novel atomic-level oligomer model. In our model, each Aβ42 protein forms a single β-sheet with three β-strands in an antiparallel arrangement. Each β-sheet consists of four Aβ42 molecules in a head-to-tail arrangement. Four β-sheets are packed together in a face-to-back fashion. The stacking of identical segments between different β-sheets within an oligomer suggests that prefibrillar oligomers may interconvert with fibrils via strand rotation, wherein β-strands undergo an ∼90° rotation along the strand direction. This work provides insights into rational design of therapeutics targeting the process of interconversion between toxic oligomers and non-toxic fibrils.

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Secondary structure and transmembrane topology analysis of the N-terminal domain of the inner membrane protein EccE1 from M. smegmatis using site-directed spin labeling EPR

The introduction of multidrug treatment regimens has dramatically prolonged the progression and survival of AIDS patients. However, the success of the long-term treatment has been hindered by strains of HIV that are increasingly resistant to inhibitors of targets such as HIV protease (HIV PR). Therefore, the need for a thorough understanding of the structure and dynamics of HIV PR and how these are altered in resistant mutants is crucial for the design of more effective treatments. Crystal structures of unbound HIV PR show significant heterogeneity and often have extensive crystal packing interactions. Recent site-directed spin labeling (SDSL) and double electron-electron resonance (DEER) spectroscopy studies characterized flap conformations in HIV-1 protease in an inhibited and uninhibited form and distinguished the extent of flap opening in an unbound form. However, the correlation between EPR-measured interspin distances and structural/dynamic features of the flaps has not been established. In this report, we link EPR-based data and 900 ns of MD simulation in explicit water to gain insight into the ensemble of conformations sampled by HIV PR flaps in solution, both in the presence and in the absence of an FDA-approved HIV PR inhibitor.