Substrate specificity of human apurinic/apyrimidinic endonuclease APE1 in the nucleotide incision repair pathway.

Human apurinic/apyrimidinic (AP) endonuclease APE1 catalyses the hydrolysis of phosphodiester bonds on the 5' side of an AP-site (in the base excision repair pathway) and of some damaged nucleotides (in the nucleotide incision repair pathway). The range of substrate specificity includes structurally unrelated damaged nucleotides. Here, to examine the mechanism of broad substrate specificity of APE1, we performed pulsed electron-electron double resonance (PELDOR) spectroscopy and pre-steady-state kinetic analysis with Förster resonance energy transfer (FRET) detection of DNA conformational changes during DNA binding and lesion recognition. Equilibrium PELDOR and kinetic FRET data revealed that DNA binding by APE1 leads to noticeable damage-dependent bending of a DNA duplex. Molecular dynamics simulations showed that the damaged nucleotide is everted from the DNA helix and placed into the enzyme's binding pocket, which is formed by Asn-174, Asn-212, Asn-229, Ala-230, Phe-266 and Trp-280. Nevertheless, no damage-specific contacts were detected between these amino acid residues in the active site of the enzyme and model damaged substrates containing 1,N6-ethenoadenosine, α-adenosine, 5,6-dihydrouridine or F-site. These data suggest that the substrate specificity of APE1 is controlled by the ability of a damaged nucleotide to flip out from the DNA duplex in response to an enzyme-induced DNA distortion.

Conformation, self-aggregation, and membrane interaction of peptaibols as studied by pulsed electron double resonance spectroscopy.

Pulsed EPR methods, in particular pulsed electron double resonance (PELDOR) [or double electron-electron resonance (DEER)], are very sensitive to the dipole ··· dipole interaction between electron spins in a pair of free radicals. Using PELDOR, the conformations of a number of double radical-containing biomolecules have been determined. In this review article, we focused our attention on the application of this spectroscopy to nitroxide-labeled peptaibols. This is an emerging class of naturally occurring, relatively short, linear, helical peptide molecules endowed with hydrophobic character, capability to interact with and to alter the structure of membranes, and antibiotic activity. We extracted detailed information on the secondary structures of specifically site-directed, double nitroxide-labeled peptaibols under a variety of experimental conditions, including biologically relevant environments. Moreover, we examined in-depth peptaibol clustering, related to the marked propensity of these molecules to undergo self-association in model and whole-cell membrane systems, using mainly mono-nitroxide-containing synthetic analogs. Finally, based on the PELDOR data accumulated, we proposed models of supramolecular (quaternary) structures of peptaibols and their binding modes to membranes.

Peptides on the surface. PELDOR data for spin-labeled alamethicin F50/5 analogues on organic sorbent.

The PELDOR technique was used to obtain the spectra of distances between spin labels for mono and double TOAC substituted analogues of [Glu(OMe)(7,18,19)] alamethicin F50/5 (Alm') peptaibiotic on the surface of the organic sorbent Oasis HLB and in ethanol solution at 77 K. For the double-labeled Alm', the free radical probes are at positions 1 and 16 (Alm'1,16). The intra- and intermolecular contributions to the PELDOR time traces were separated, with regard to the fractality of the system studied. We established that on HLB the labeled Alm' molecules are prone to aggregation. The distance spectra for Alm'1,16 show that, in both adsorbed state and in ethanol solution, the peptaibiotic is predominantly folded in the α-helix conformation. We assign the asymmetry of the distance spectrum in both cases to the occurrence of an admixture of more elongated α/3(10)-helical conformers. The portion of these conformers is higher for the peptide adsorbed on HLB. We speculate that both the broadening of the basic spectrum line at r(max) = 2.0 nm and the increase in the contribution of elongated conformers might be associated with the spread of the peptaibiotic adsorption sites on HLB as compared with the more uniform Alm'1,16 trap structure in frozen ethanol solution. The aggregates of mono-labeled Alm'1 and Alm'16 also studied. The intermolecular distance spectrum for Alm'1 on HLB is shifted toward longer distances as compared with those of Alm'16. This result suggests that in the aggregates Alm' molecules are preferentially oriented with their C-terminal regions in the vicinity.

Synthesis and conformational properties of a TOAC doubly spin-labeled analog of the medium-length, membrane active peptaibiotic ampullosporin A as revealed by CD, fluorescence, and EPR spectroscopies.

We describe the challenging solid-phase synthesis of the medium-length (14 amino-acid residues) peptaibiotic ampullosporin A, originally extracted from the fungus Sepedonium ampullosporum, and an analog doubly spin labeled (at positions 3 and 13) with the stable nitroxyl free-radical 4-amino-1-oxyl-2,2,6,6-tetramethylpiperidine-4-carboxylic acid (TOAC). The results of a circular dichrosim investigation in methanol strongly support the view that both peptides are essentially right-handed helical, in particular endowed with a large population of α-helical conformers. We also observed a significant quenching effect from the TOAC(3) nitroxyl radical on the fluorescence of Trp(1), compatible with that expected when both residues are closely located on the same helix segment. Combined continuous wave and pulsed electron-electron double resonance electron paramagnetic resonance methodologies converge on the conclusion obtained from the other aforementioned spectroscopies, namely, that the [TOAC(3,13)] ampullosporin A analog is mostly folded in the α-helical conformation. A liposome leakage assay demonstrated that the membrane-modifying properties of this bis-labeled analog are remarkable and even slightly superior to those of the natural peptaibiotic itself.

Structure of self-aggregated alamethicin in ePC membranes detected by pulsed electron-electron double resonance and electron spin echo envelope modulation spectroscopies.

PELDOR spectroscopy was exploited to study the self-assembled super-structure of the [Glu(OMe)(7,18,19)]alamethicin molecules in vesicular membranes at peptide to lipid molar ratios in the range of 1:70-1:200. The peptide molecules were site-specifically labeled with TOAC electron spins. From the magnetic dipole-dipole interaction between the nitroxides of the monolabeled constituents and the PELDOR decay patterns measured at 77 K, intermolecular-distance distribution functions were obtained and the number of aggregated molecules (n approximately 4) was estimated. The distance distribution functions exhibit a similar maximum at 2.3 nm. In contrast to Alm16, for Alm1 and Alm8 additional maxima were recorded at 3.2 and approximately 5.2 nm. From ESEEM experiments and based on the membrane polarity profiles, the penetration depths of the different spin-labeled positions into the membrane were qualitatively estimated. It was found that the water accessibility of the spin-labels follows the order TOAC-1 > TOAC-8 approximately TOAC-16. The geometric data obtained are discussed in terms of a penknife molecular model. At least two peptide chains are aligned parallel and eight ester groups of the polar Glu(OMe)(18,19) residues are suggested to stabilize the self-aggregate superstructure.

PELDOR conformational analysis of bis-labeled alamethicin aggregated in phospholipid vesicles.

Alamethicin (Alm) is a linear peptide antibiotic of great interest for its capability to form self-assembled ion channels in lipid membranes. Here, the pulsed electron-electron double resonance technique was used to obtain unique conformational information on the aggregated peptide in the lipid membrane-bound state. Since a specific helical conformation implies a given length to the peptide molecule, a distance r was measured at the nanometer scale via the electron dipole-dipole interaction between two 2,2,6,6-tetramethylpiperidine-1-oxyl-4-amino-4-carboxylic acid spin labels synthetically incorporated at positions 1 and 16 of this 19-mer peptide. Two data sets were collected (at 77 K): (i) from aggregates of Alm in hydrated egg-yolk phosphocholine (ePC) vesicles (at peptide-to-lipid ratios of 1:200 and 1:75) and (ii) from nonaggregated Alm in pure (nonhydrated) ePC and in solvents of different polarity. The intramolecular distance between the two labels obtained in this manner is in excellent agreement with that calculated on the basis of an almost fully developed alpha-helical conformation for this peptide and is found to be independent of the molecular aggregated state and the environment polarity as well.

Solvent effects on the secondary structure of the membrane-active zervamicin determined by PELDOR spectroscopy.

Zervamicin is a voltage-gated ion-channel-forming peptide. Channels are generally considered to be formed by first insertion of amphipathic molecules into the phospholipid bilayer, followed by self-assembly of a variable number of transmembrane helices. We have studied the length of the peptide structure to address the question whether this peptide is long enough to span the phospholipid bilayer. The pulsed electron-electron double resonance (PELDOR) spectroscopic technique was used to determine the length of the helical molecule in membrane-mimicking solvents. This was achieved from the distance-related dipole-dipole interaction between spin labels, which were located at both ends of the linear peptide chain. The data were obtained by using samples of frozen glassy solutions of MeOH, MeOH/toluene, and MeOH/CHCl(3). Contributions of inter- and intramolecular interactions of spin labels were separated to analyze the intramolecular interaction and the distance distribution function between the labels. It is shown that the main maximum of the distribution functions is located at a distance of ca. 3.3 nm, and this distance appears to be only slightly dependent on the solvent composition. The distribution function was observed to narrow after addition of either CHCl(3) or toluene to MeOH. This effect is rationalized in terms of a decreased mobility of the terminal amino acid residues. By molecular-dynamics simulations, it was shown that the conformation, corresponding with the predominant distance found by PELDOR, agrees well with the mixed alpha/3(10)-helical that was previously determined by NMR. However, in the case toluene was added to the MeOH solution to further increase the hydrophobicity of the environment of the membrane-active peptide, the distribution function gives rise to a minor fraction (7-8%) with a distance of 4.2 nm. This distance corresponds most likely to the more extended 2(7)-helix structure.

Supramolecular structure of self-assembling alamethicin analog studied by ESR and PELDOR.

Three analogs of alamethicin F50/5, labelled with the TOAC (='2,2,6,6-tetramethylpiperidin-1-oxyl-4-amino-4-carboxylic acid') spin label at positions 1 (Alm1), 8 (Alm8), and 16 (Alm16), resp., were studied by Electron-Spin-Resonance (ESR) and Pulsed Electron-Electron Double-Resonance (PELDOR) techniques in solvents of different polarity to investigate the self-assembly of amphipathic helical peptides in membrane-mimicking environments. In polar solvents, alamethicin forms homogeneous solutions. In the weakly polar chloroform/toluene 1 : 1 mixture, however, this peptide forms aggregates that are detectable at 293 K by ESR in liquid solution, as well as by PELDOR in frozen, glassy solution at 77 K. In liquid solution, free alamethicin molecules and their aggregates show rotational-mobility correlation times tau(r) of 0.87 and 5.9 ns, resp. Based on these values and analysis of dipole-dipole interactions of the TOAC labels in the aggregates, as determined by PELDOR, the average number N of alamethicin molecules in the aggregates is estimated to be less than nine. A distance-distribution function between spin labels in the supramolecular aggregate was obtained. This function exhibits two maxima: a broad one at a distance of 3.0 nm, and a wide one at a distance of ca. 7 nm. A molecular-dynamics (MD)-based model of the aggregate, consisting of two parallel tetramers, each composed of four molecules arranged in a 'head-to-tail' fashion, is proposed, accounting for the observed distances and their distribution.