Pulsed Electron-electron Double Resonance Data Research Articles

Alamethicin self-assembling in lipid membranes: concentration dependence from pulsed EPR of spin labels.

The antimicrobial action of the peptide antibiotic alamethicin (Alm) is commonly related to peptide self-assembling resulting in the formation of voltage-dependent channels in bacterial membranes, which induces ion permeation. To obtain a deeper insight into the mechanism of channel formation, it is useful to know the dependence of self-assembling on peptide concentration. With this aim, we studied Alm F50/5 spin-labeled analogs in a model 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) membrane, for peptide-to-lipid (P/L) ratios varying between 1/1500 and 1/100. Pulsed electron-electron double resonance (PELDOR) spectroscopy reveals that even at the lowest concentration investigated, the Alm molecules assemble into dimers. Moreover, under these conditions, electron spin echo envelope modulation (ESEEM) spectroscopy of D2O-hydrated membranes shows an abrupt change from the in-plane to the trans-membrane orientation of the peptide. Therefore, we hypothesize that dimer formation and peptide reorientation are concurrent processes and represent the initial step of peptide self-assembling. By increasing peptide concentration, higher oligomers are formed. A simple kinetic model of equilibrium among monomers, dimers, and pentamers allows for satisfactorily describing the experimental PELDOR data. The inter-label distances in the oligomers obtained from PELDOR experiments become better resolved with increasing P/L ratio, thus suggesting that the supramolecular organization of the higher-order oligomers becomes more defined.

Sparse Labeling PELDOR Spectroscopy on Multimeric Mechanosensitive Membrane Channels

Pulse electron paramagnetic resonance (EPR) is being applied to ever more complex biological systems comprising multiple subunits. Membrane channel proteins are of great interest as pulse EPR reports on functionally significant but distinct conformational states in a native environment without the need for crystallization. Pulse EPR, in the form of pulsed electron-electron double resonance (PELDOR), using site-directed spin labeling, is most commonly employed to accurately determine distances (in the nanometer range) between different regions of the structure. However, PELDOR data analysis is more challenging in systems containing more than two spins (e.g., homomultimers) due to distorting multispin effects. Without suppression of these effects, much of the information contained in PELDOR data cannot be reliably retrieved. Thus, it is of utmost importance for future PELDOR applications in structural biology to develop suitable approaches that can overcome the multispin problem. Here, two different approaches for suppressing multispin effects in PELDOR, sparse labeling of the protein (reducing the labeling efficiency f) and reducing the excitation probability of spins (λ), are compared on two distinct bacterial mechanosensitive channels. For both the pentameric channel of large conductance (MscL) and the heptameric channel of small conductance (MscS) of Escherichia coli, mutants containing a spin label in the cytosolic or the transmembrane region were tested. Data demonstrate that distance distributions can be significantly improved with either approach compared to the standard PELDOR measurement, and confirm that λ < 1/(n−1) is needed to sufficiently suppress multispin effects (with n being the number of spins in the system). A clear advantage of the sparse labeling approach is demonstrated for the cytosolic mutants due to a significantly smaller loss in sensitivity. For the transmembrane mutants, this advantage is less pronounced but still useful for MscS, but performance is inferior for MscL possibly due to structural perturbations by the bulkier diamagnetic spin label analog.

Intersubunit distances in full-length, dimeric, bacterial phytochrome Agp1, as measured by pulsed electron-electron double resonance (PELDOR) between different spin label positions, remain unchanged upon photoconversion

Bacterial phytochromes are dimeric light-regulated histidine kinases that convert red light into signaling events. Light absorption by the N-terminal photosensory core module (PCM) causes the proteins to switch between two spectrally distinct forms, Pr and Pfr, thus resulting in a conformational change that modulates the C-terminal histidine kinase region. To provide further insights into structural details of photoactivation, we investigated the full-length Agp1 bacteriophytochrome from the soil bacterium Agrobacterium fabrum using a combined spectroscopic and modeling approach. We generated seven mutants suitable for spin labeling to enable application of pulsed EPR techniques. The distances between attached spin labels were measured using pulsed electron-electron double resonance spectroscopy to probe the arrangement of the subunits within the dimer. We found very good agreement of experimental and calculated distances for the histidine-kinase region when both subunits are in a parallel orientation. However, experimental distance distributions surprisingly showed only limited agreement with either parallel- or antiparallel-arranged dimer structures when spin labels were placed into the PCM region. This observation indicates that the arrangements of the PCM subunits in the full-length protein dimer in solution differ significantly from that in the PCM crystals. The pulsed electron-electron double resonance data presented here revealed either no or only minor changes of distance distributions upon Pr-to-Pfr photoconversion.

Structural Changes of a Doubly Spin-Labeled Chemically Driven Molecular Shuttle Probed by PELDOR Spectroscopy.

Gaining detailed information on the structural rearrangements associated with stimuli-induced molecular movements is of utmost importance for understanding the operation of molecular machines. Pulsed electron-electron double resonance (PELDOR) was employed to monitor the geometrical changes arising upon chemical switching of a [2]rotaxane that behaves as an acid-base-controlled molecular shuttle. To this aim, the rotaxane was endowed with stable nitroxide radical units in both the ring and axle components. The combination of PELDOR data and molecular dynamic calculations indicates that in the investigated rotaxane, the ring displacement along the axle, caused by the addition of a base, does not alter significantly the distance between the nitroxide labels, but it is accompanied by a profound change in the geometry adopted by the macrocycle.

Ligand Induced Conformational Changes of a Membrane Transporter in E. coli Cells Observed with DEER/PELDOR.

An unrealized goal in structural biology is the determination of structure and conformational change at high resolution for membrane proteins within the cellular environment. Pulsed electron-electron double resonance (PELDOR) is a well-established technique to follow conformational changes in purified membrane protein complexes. Here we demonstrate the first proof of concept for the use of PELDOR to observe conformational changes in a membrane protein in intact cells. We exploit the fact that outer membrane proteins usually lack reactive cysteines and that paramagnetic spin labels entering the periplasm are selectively reduced to achieve specific labeling of the cobalamin transporter BtuB in Escherichia coli. We characterize conformational changes in the second extracellular loop of BtuB upon ligand binding and compare the PELDOR data with high-resolution crystal structures. Our approach avoids detergent extraction, purification, and reconstitution usually required for these systems. With this approach, structure, function, conformational changes, and molecular interactions of outer membrane proteins can be studied at high resolution in the cellular environment.

Peptides on the Surface: Spin-Label EPR and PELDOR Study of Adsorption of the Antimicrobial Peptides Trichogin GA IV and Ampullosporin A on the Silica Nanoparticles

The properties of antimicrobial peptides adsorbed on inorganic or organic surfaces are of interest for their potential applications in intracellular drug delivery. In this work, continuous-wave (CW) electron paramagnetic resonance (EPR) and pulsed electron-electron double resonance (PELDOR) techniques were applied to study adsorption of the short-sequence trichogin GA IV and the medium-length sequence ampullosporin A antimicrobial peptides on the monodisperse colloidal silica nanospheres of 20 nm diameter. The results obtained by CW EPR support the view that the adsorbed peptides form close-packed clusters. PELDOR data show that both trichogin and ampullosporin adsorbed on the silica surface possess a more disordered conformation as compared to that in solution. For ampullosporin, disordering is much more pronounced than for trichogin. After desorption, the peptides restored their conformations; upon adsorption the peptides in some cases may lose partly their biradical character.

Energy Landscapes and Catalysis in Nitric-oxide Synthase

Nitric oxide (NO) plays diverse roles in mammalian physiology. It is involved in blood pressure regulation, neurotransmission, and immune response, and is generated through complex electron transfer reactions catalyzed by NO synthases (NOS). In neuronal NOS (nNOS), protein domain dynamics and calmodulin binding are implicated in regulating electron flow from NADPH, through the FAD and FMN cofactors, to the heme oxygenase domain, the site of NO generation. Simple models based on crystal structures of nNOS reductase have invoked a role for large scale motions of the FMN-binding domain in shuttling electrons from the FAD-binding domain to the heme oxygenase domain. However, molecular level insight of the dynamic structural transitions in NOS enzymes during enzyme catalysis is lacking. We use pulsed electron-electron double resonance spectroscopy to derive inter-domain distance relationships in multiple conformational states of nNOS. These distance relationships are correlated with enzymatic activity through variable pressure kinetic studies of electron transfer and turnover. The binding of NADPH and calmodulin are shown to influence interdomain distance relationships as well as reaction chemistry. An important effect of calmodulin binding is to suppress adventitious electron transfer from nNOS to molecular oxygen and thereby preventing accumulation of reactive oxygen species. A complex landscape of conformations is required for nNOS catalysis beyond the simple models derived from static crystal structures of nNOS reductase. Detailed understanding of this landscape advances our understanding of nNOS catalysis/electron transfer, and could provide new opportunities for the discovery of small molecule inhibitors that bind at dynamic protein interfaces of this multidimensional energy landscape.

Refined Distances Between Paramagnetic Centers of a Multi‐Copper Nitrite Reductase Determined by Pulsed EPR (iDEER) Spectroscopy

Refined Distances Between Paramagnetic Centers of a Multi‐Copper Nitrite Reductase Determined by Pulsed EPR (<i>i</i>DEER) Spectroscopy

Measuring Transmembrane Helix Separation on the MscS Mechanosensitive Channel using Pulsed Electron-Electron Double Resonance (PELDOR) Spectroscopy

The heptameric mechanosensitive channel of small conductance (MscS) provides an essential function in Escherichia coli as it prevents cell lysis by opening in response to increased bilayer tension, during extreme osmotic shock. The gating of MscS has been extensively studied by three approaches: X-ray crystallography [1], cwEPR [2] spectroscopy and EMD simulations [3], but each of them has defined different closed and open structures of the channel. The proposed models report very different arrangements of the transmembrane helices. To resolve the discrepancy, we have attached spin labels to cysteine mutants on key structural elements within all three MscS transmembrane helices, specifically chosen to discriminate between the competing models. These distances from multiple mutants provide an independent assessment of the validity of the competing models. In addition, they offer the advantage of measurements on MscS in solution under physiological conditions. The resulting pulsed electron-electron double resonance (PELDOR) spectra allow the accurate measurement of transmembrane helix separation, offering a direct comparison for the different models. The distance distributions for the open crystal structure of MscS match the experimental data [4]. We also report two new crystal structures of spin labeled MscS which are in complete agreement with the PELDOR data and demonstrate the accuracy of PELDOR for complex ion channels. PELDOR is a powerful experimental tool which can be used for interrogating the conformation of transmembrane regions of multimeric membrane proteins.[1] Wang et al., Science 321, 1179 (2008).[2] Vasquez et al., Science 321, 1210 (2008).[3] Akitake et al., NSMB 14, 1141 (2007).[4] Pliotas et al., PNAS (doi/10.1073/pnas.1202286109) (2012)

An algorithm to analyze PELDOR data of rigid spin label pairs

Pulsed Electron-electron Double Resonance (PELDOR) is a method frequently used to determine the distances between paramagnetic centers in biomacromolecules on the nanometer scale. A standard algorithm for determination of distances from the experimental data assumes that all possible mutual orientations of the spin labels are equally probable. However, in many applications the mobility of the spin labels attached to large molecules can be significantly restricted. In order to determine the total PELDOR signal in this case, the individual contributions of each rigid biradical should be explicitly calculated for the given frequencies of the probe and pump pulses. The solution of the inverse problem of determination of the ensemble of molecular structures that fit the experimental PELDOR data acquired at multiple microwave frequencies and magnetic fields has proven to be a non-trivial task, especially, when no information about the molecular structure under study is available. In this work we present a fitting algorithm that reconstructs experimental data by searching for an optimal combination of presimulated PELDOR time traces for nitroxide biradicals with all relative orientations and with inter-spin distances in the experimentally accessible range. The generated library of PELDOR time traces has been employed to excellently fit experimental data containing orientation selection effects gathered on model biradical systems.

Conformational Properties of the Spin-Labeled Tylopeptin B and Heptaibin Peptaibiotics Based on PELDOR Spectroscopy Data

X-Band pulsed electron–electron double resonance (PELDOR) spectroscopy was used to investigate for the first time the magnetic dipole–dipole interaction between spin labels for frozen glassy methanol solutions at 77 K of double spin-labeled, medium-length peptaibiotics, namely, tylopeptin B and heptaibin. This study was conducted on tylopeptin labeled at positions 3 and 13 (T313) and heptaibin labeled at positions 2 and 14 (H214). PELDOR data analysis was carried out using the theory developed for short inter-spin distances. The distance distribution functions between spin labels for T313 (maximum at 1.76 nm, half-width of 0.07 nm) and H214 (maximum at 2.30 nm, half-width of 0.065 nm) were determined. It is found that the distance distribution function for peptide T313 has the Gaussian shape. The main part of the distance spectrum for H214 has Gaussian shape and additional less intensive broad lines are shifted to high distances range 2.5–3.5 nm. The upper limit of distance spectrum in this case corresponds approximately to the length of extended peptide molecule and the number of such configurations is low. Intramolecular distances between the labels at maxima observed allowed us to assign α-helical conformation to T313 and 310-helical structure to H214 in methanol solution.

PELDOR analysis of enzyme-induced structural changes in damaged DNA duplexes

PELDOR (pulsed electron-electron double resonance) spectroscopy was applied to determine spin-spin distances in spin-labeled DNA duplexes (13-mer and 17-mer) containing the damaged sites 8-oxoguanine or uncleavable abasic site analogue tetrahydrofuran. The lesions were located in one strand of the DNA, and two nitroxyl spin labels were attached at the 5'- and 3'-ends of the complementary strand. PELDOR data allow us to obtain distances between the two spin labels in DNAs, which turned out to be around 5 nm for the 13-mer DNA and around 6 nm for 17-mer DNA. Results of PELDOR measurements were supported by molecular dynamics calculations. Study of the interaction of DNA fragments with DNA repair enzyme 8-oxoguanine-DNA glycosylase from E. coli (Fpg protein) showed that this interaction leads to a noticeable decrease of the distance between spin labels, which indicates the enzyme-induced bending of the DNA duplex. This bending may be important for the mechanisms of recognition of damaged sites by DNA repair enzymes.

Pulsed Electron−Electron Double-Resonance Determination of Spin-Label Distances and Orientations on the Tetrameric Potassium Ion Channel KcsA

Pulsed electron-electron double-resonance (PELDOR) measurements are presented from the potassium ion channel KcsA both solubilized in detergent and reconstituted in lipids. Site-directed spin-labeling using (1-oxyl-2,2,5,5-tetramethyl-3-pyrrolin-3-yl)methyl methanethiosulfonate was performed with a R64C mutant of the protein. The orientations of the spin-labels in the tetramer were determined by PELDOR experiments performed at two magnetic field strengths (0.3 T/X-band and 1.2 T/Q-band) and variable probe frequency. Quantitative simulation of the PELDOR data supports a strongly restricted nitroxide, oriented at an angle of 65 degrees relative to the central channel axis. In general, poorer quality PELDOR data were obtained from membrane-reconstituted preparations compared to soluble proteins or detergent-solubilized samples. One reason for this is the reduced transverse spin relaxation time T(2) of nitroxides due to crowding of tetramers within the membrane that occurs even at low protein to lipid ratios. This reduced T(2) can be overcome by reconstituting mixtures of unlabeled and labeled proteins, yielding high-quality PELDOR data. Identical PELDOR oscillation frequencies and their dependencies on the probe frequency were observed in the detergent and membrane-reconstituted preparations, indicating that the position and orientation of the spin-labels are the same in both environments.

PELDOR study of conformations of double-spin-labeled single- and double-stranded DNA with non-nucleotide inserts

DNA fragments were synthesized consisting of 12 nucleotides and containing non-nucleotide inserts of different length in the middle. Two nitroxide spin labels 4-amino-2,2,6,6-tetramethylpiperidine-1-oxyl were attached at the two ends of the molecules. Single-stranded DNAs and double-stranded DNAs (DNA duplexes) in frozen at 77 K glassy water/glycerol solutions were studied using pulsed electron-electron double resonance (PELDOR). The distance distributions between two spin labels in molecules were obtained from PELDOR data using Tikhonov regularization algorithm, and were found to be close to the Gaussian functions. Experimental PELDOR data were fitted by adjusting precisely the maximum position and the width of these functions. The obtained results show that duplexes possess a substantially narrower distribution, as compared to the single-stranded DNAs. Introduction of a non-nucleotide insert 2-hydroxymethyl-3-hydroxy-tetrahydrofuran leads to a slight but nevertheless detectable decrease of the mean distance between two spin labels. This decrease may be attributed to bending of the molecule around the insert site, by an angle of approximately 20 degrees . An introduction of a non-nucleotide insert bis-(di-ethyleneglycol)-phosphate results in a remarkable broadening of the distance distribution. The results evidence that PELDOR of spin-labeled DNA molecules may be used as a "molecular ruler" for studying the influence of local damages on the DNA conformations.

Ferro- and antiferromagnetic exchange coupling constants in PELDOR spectra

Pulsed electron electron double resonance (PELDOR) is a well-established method for measuring nanometer distances between paramagnetic centres. Here, we demonstrate on three rigid and conjugated biradicals how the presence of an exchange coupling constant J and its distribtion DeltaJ influences PELDOR data and its analysis. In principle two combinations of J and D fulfill the experimental data in each case. The correct one, including the sign of J, can be determined via simulations in case the two halves of the Pake pattern are separated enough.

Solvent effect on the distance distribution between spin labels in aggregated spin labeled trichogin GA IV dimer peptides as studied by pulsed electron–electron double resonance

Pulsed electron–electron double resonance (PELDOR) was used to study aggregate formation in frozen glassy solutions of mono- and double-spin labeled trichogin GA IV dimers in a toluene–methanol mixture. The modified method proposed and used for the distance distribution function calculation from the PELDOR data. Distance distribution functions between spin labels in the peptide molecules and their aggregates in solution were determined as a function of solvent composition. Double-labeled peptide molecules in aggregates in solutions with low methanol content display two types of structures, i.e. the α-helix with a 2.8 nm distance between labels and the 310-helix with a 3.2 nm distance between labels. As the methanol content of the solvent increases, a part of conformations at 3.2 nm changes. An increase of the methanol content leads to disruption of the aggregates and a change to the peptide conformation as well. In pure methanol peptides fail to form aggregates and a wide distribution of distances between labels centered at 3 nm were observed.

Aggregation of Spin Labeled Trichogin GA IV Dimers: Distance Distribution between Spin Labels in Frozen Solutions by PELDOR Data

Pulsed electron−electron double-resonance (PELDOR) and CW-ESR spectroscopies were used to study the dipole−dipole interaction of spin labels in frozen glassy solutions of mono- and double-labeled analogues of the 22-residue, the head-to-tail covalent dimer of the peptaibol antibiotic trichogin GA IV. The [TOAC-1] and [TOAC-1,19] dimers were studied in methanol and in a chloroform−toluene mixture. It was shown these dimer molecules do not form aggregates in methanol. However, in chloroform−toluene, the PELDOR signal of the mono-labeled dimer shows oscillations, due to the dipole−dipole interaction of the nitroxide spin labels. From the signal decay, the number of molecules per aggregate was estimated to be ∼2−3, depending on the concentration used. The contributions of inter- and intra-aggregate interactions of spin labels to the PELDOR signal decay were separated. The distance distribution functions of the intra-aggregate interactions range from 3.0 to 4.5 nm. The maxima are observed at 3.4 nm. From the P...