Rotational diffusion and intermolecular collisions of a spin labeled alpha-helical peptide determined by electron spin echo spectroscopy.

Short peptides that are composed mainly of alanine have recently been shown to form alpha-helices in aqueous solution at low temperature (Marqusee, S., and R. L. Baldwin. 1987. Proc. Natl. Acad. Sci. 84:8898-8902; Marqusee, S., V. H. Robbins, and R. L. Baldwin. 1989. Proc. Natl. Acad. Sci. USA. 86:5286-5290). These peptides are excellent models for probing structure and dynamics in isolated helical domains. In previous work we have designed and synthesized spin labeled analogs of these helix-forming peptides and we have shown that these analogs retain the folding characteristics of the parent peptide (Todd, A. P., and G. L. Millhauser. 1991. Biochemistry. 30:5515-5523). Using conventional continuous wave electron spin resonance (CW ESR) we have further shown that local motion is more pronounced near the helix amino terminus than in the central region as the peptide is thermally unfolded (Miick, S. M., A. P. Todd, and G. L. Millhauser. 1991. Biochemistry. 30:9498-9503). In this present work we use electron spin echo (ESE) spectroscopy to further refine our understanding of the solution dynamics of the 3K-8 peptide, which is a 16-mer with a nitroxide spin label attached at position 8. We find that the spin echo decays are well described by a single exponential function and that the determined correlation times are close to those previously derived from CW experiments. Variable concentration ESE experiments have directly revealed Heisenberg spin exchange (HSE) interactions and we find that the interpeptide collision rate is near to that expected for a free species in solution.(ABSTRACT TRUNCATED AT 250 WORDS)     

Base dynamics of local Z-DNA conformations as detected by electron paramagnetic resonance with spin-labeled deoxycytidine analogues

Conformation detection and base dynamics of spin-labeled Z-DNA have been investigated by electron paramagnetic resonance (EPR) spectroscopy. The two synthesized and characterized probes used in this study were C(5)-nitroxide-labeled 2'-deoxycytidine 5'-triphosphates, pppDCAT and pppDCAVAT, which serve as suitable substrates for Micrococcus luteus DNA polymerase. Enzymatic incorporation of these probes into (dG-dC)n yields the EPR-active alternating copolymers (dG-dC,DCAT)n and (dG-dC,-DCAVAT)n. These polymers assume typical B- and Z-DNA conformations under respective low (0.1 M NaCl) and high (4.5 M NaCl) salt conditions, as evidenced by their UV-circular dichroism spectra. The EPR line shape of (dG-dC,DCAT)n in Z-form is unique and significantly different from the B-form EPR spectrum. A similar observation is made for (dG-dC,DCAVAT)n. Thus, the EPR line shapes of these spin-labeled DNAs are indicative of their local conformations. The EPR spectra, analyzed with a previously published motional model [Kao, S.-C., Polnaszek, C.F., Toppin, C.R., & Bobst, A.M. (1983) Biochemistry 22, 5563-5568], indicate tau perpendicular values of 4 and 7 ns for the B- and Z-forms, respectively. Therefore, the base dynamics of Z-DNA are about two times slower than in B-DNA.     

Radiolysis of spin-labeled DNA: an electron spin resonance investigation

The reactions of free and DNA-bound 2,2,5,5-tetramethylpyrrolidine-N-oxyl (PROXYL) probes with radicals generated during radiolysis of dilute aqueous solutions of DNA were examined. For the free PROXYL probe in deaerated solution with each of the four nucleotides (dAMP, dCMP, dGMP, and TMP) it was found that the pyrimidine radicals were more reactive toward the probe than were the purine radicals. Reactions of the electron adduct of TMP and the hydroxyl radical adducts of dAMP, dGMP, and TMP with the probe resulted in little or no reduction of the probe. For TMP these results are consistent with the fact that both the protonated electron and hydroxyl radical adducts of TMP will covalently bind to the nitroxide function of the probe. Reduction of the PROXYL probe was observed in reactions with the hydroxyl radical adduct of dCMP and with the electron adducts of dAMP, dCMP, and dGMP. Results of the radiolysis of the free PROXYL probe in deaerated dilute solution of DNA suggest that the PROXYL probe protects the DNA from water radical attack as the ratio of DNA bases to PROXYL probe increases above 50:1. Reactions of DNA-bound probes are dependent on the depth of the nitroxide function in relation to the major groove of the DNA helix. Two probes with tether lengths which are less than the depth of the major groove show an expected increase in reactions with DNA base radicals as compared to a probe with a tether that extends beyond the groove. The longer probe is involved largely in reactions with sugar and water radicals along the periphery of the DNA helix. In the presence of oxygen, there is a dramatic decrease in the loss of both the free and DNA-bound probes due to the lack of reaction of these probes with peroxyl radicals formed by the addition of molecular oxygen to DNA radicals.     

Translational diffusion of lipid monomers determined by spin label electron spin resonance

The collision rates between spin-labelled valeric acid in water, and between the corresponding mixed-chain, spin-labelled phosphatidylcholine in water-methanol mixtures, and also between spin-labelled phosphatidylcholine monomers and micelles in water have been determined from the spin-spin broadening of the electron spin resonance spectrum. In each case the second order rate constants are consistent with a diffusion-controlled process. For spin-labelled valeric acid in water the translational diffusion coefficient at 20°C is 3.4 · 10⁻⁶ cm² · s⁻¹, and for spin-labelled phosphatidylcholine varies between 2.3 · 10⁻⁶ and 3.8 · 10⁻⁶ cm² · s⁻¹ within the range 44 to 88 wt% methanol. The spin-labelled phosphatidylcholine monomer diffusion coefficient in water at 20°C is 2.4 · 10⁻⁶ cm² · s⁻¹, deduced from the monomer-micelle association rate, with an activation energy of 4.0 kcal · mol⁻¹. The much slower on-rates for association of lipid monomers with phospholipid bilayer vesicles reported in the literature, therefore indicate that incorporation into bilayers is not a diffusion-controlled process.     

The effects of actin on the electron spin resonance of spin-labeled myosin

Myosin and heavy meromyosin have been spin labeled at either the S₁ or S₂ thiol groups, and their interaction with F-actin has been studied by electron spin resonance, both in the absence of substrate and during the hydrolysis of ATP. The spectrum of myosin labeled at either group indicates strong immobilization of the label. In the absence of substrate, actin added to S₁-labeled myosin slightly increases the separation of the outer spectral peaks, indicating a decrease in the mobility of the spin label. Actin also reduces the microwave power required to saturate the esr signal of S₁-labeled myosin or heavy meromyosin. The latter phenomenon is a more sensitive measure of the actin-myosin interaction than the spectral change seen in the absence of saturation. This suggests that saturation measurements may provide a more sensitive method of detecting changes in the environment of slowly tumbling nitroxide radicals than spectral measurements carried out in the absence of saturation. The decrease in the amplitude of the spectrum on adding actin at saturating microwave power was used to determine the stoichiometry of the interaction between actin and heavy meromyosin. This decrease is maximal when 2 moles of actin monomer are added per mole of heavy meromyosin and is reversed when actin and myosin are dissociated by ATP. During the steady state hydrolysis of ATP, actin had no detectable effect on the spectrum of S₁-labeled myosin. It can be concluded that spin labels bound to the S₁ groups are in a region of the myosin molecule that is affected by the interaction with actin. Actin does not affect the rate at which the bound spin label is reduced by dithiothreitol nor does the spin labeling of S₁ groups affect the activation by actin of the ATPase activity of myosin. These findings suggest that the most likely mechanism by which actin alters the mobility of labels on S₁ groups involves a change in the conformation of myosin. If a spin label is bound to the S₂ thiol groups rather than the S₁ groups, then actin has no detectable effect on the spectrum either in the presence or absence of ATP.     

ESR spectra reflect local and global mobility in a short spin-labeled peptide throughout the alpha-helix----coil transition.

A series of short alanine-based synthetic peptides (16 or 17 residues) have previously been shown to exhibit an anomalously high degree of alpha-helicity [Marqusee, S., et al. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 5286-5290; Marqusee, S., & Baldwin, R.L. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 8898-8902]. These peptides are ideal models for extracting position-dependent structural and dynamic information. Using the methanethiosulfonate nitroxide spin label (MTSSL), we labeled an analogue of the salt-bridge-stabilized "i+4" peptide, called the "i+4c", which has a specific attachment site created by replacing the central alanine with a cysteine. Circular dichroism (CD) spectra demonstrate that the i+4c-MTSSL peptide retains nearly the same helicity as the original i+4 peptide. The ESR spectra of the labeled peptide indicate no significant aggregation. ESR spectra were acquired throughout the helix-coil transition by temperature variation. From the motionally narrowed spectra, we extracted the rotational correlation times of the nitroxide label. Parallel measurements with circular dichroism enabled us to relate these parameters directly to the fractional helicity. For comparison, we followed a similar procedure with MTSSL-labeled glutathione (GS-MTSSL), a tripeptide that does not form an alpha-helix. Our results are interpreted in terms of a local tumbling volume, V(L), which reflects the portion of the peptide that reorients with the nitroxide label. At high fractional helicity, V(L) is similar to the volume expected for a 17-residue helix.     

Antioxidant capacity in rat skeletal muscle tissues determined by electron spin resonance

The amount of radical scavenging activity in muscle is unknown. The present study examines whether electron spin resonance (ESR) could measure and distinguish antioxidant capacity in muscle with different contractile and metabolic characteristics. Specimens of the soleus, plantaris, gastrocnemius (deep/surface portions), heart and diaphragm were obtained from female Wistar rats (n=7; 12 weeks old). Scavenging activity against superoxide anions in these specimens were determined by ESR using a spin-trapping chemical (5,5-dimethyl-1-pyrroline-N-oxide). The ESR signal intensity of reaction mixtures containing muscle tissues was significantly lower in the heart, soleus, diaphragm and deep portion of the gastrocnemius than in the plataris and surface portion of the gastrocnemius. Thus, the amount of scavenging activity converted into superoxide dismutase activity was the highest in the heart, and higher in the soleus, diaphragm and deep portion of the gastrocnemius than in other muscles (ANOVA, P<0.01). In addition, scavenging activity significantly correlated with citrate synthase activity (r=0.72, P<0.01, n=42) and myoglobin content (r=0.63, P<0.01, n=42). These findings suggested that ESR and spin-trapping can be detect differences in free radical scavenging activity among muscle tissues with different metabolic characteristics.     

Behavior of cholesterol and spin-labeled cholestane in model bile systems studied by electron spin resonance and synchrotron x-ray.

The behavior of mixed bile salt micelles consisting of sodium taurocholate, egg phosphatidylcholine, and cholesterol has been studied by ESR spin labeling and synchrotron x-ray scattering. Consistent with published phase diagrams, pure and mixed bile salt micelles have a limited capacity to incorporate and, hence, solubilize cholesterol. Excess cholesterol crystallizes out, a process that is readily detected both by ESR spin labeling using 3-doxyl-5 alpha-cholestane as a probe for cholesterol and synchrotron x-ray scattering. Both methods yield entirely consistent results. The crystallization of cholesterol from mixed bile salt micelles is indicated by the appearance of a magnetically dilute powder spectrum that is readily detected by visual inspection of the ESR spectra. Both the absence of Heissenberg spin exchange and the observation of a magnetically dilute powder spectrum provide evidence for the spin label co-crystallizing with cholesterol. In mixed bile salt micelles containing egg phosphatidylcholine, the solubility of cholesterol is increased as detected by both methods. With increasing content of phosphatidylcholine and increasing mole ratio cholesterol/phosphatidylcholine, the anisotropy of motion of the spin probe increases. The spin label 3-doxyl-5 alpha-cholestane is a useful substitute for cholesterol provided that it is used in dilute mixtures with excess cholesterol: the cholesterol/spin label mole ratio in these mixtures should be greater than 100. Despite the structural similarity between the two compounds, there are still significant differences in their physico-chemical properties.(ABSTRACT TRUNCATED AT 250 WORDS)     

Conformational transition of polypeptide chain elongation factor G as determined by electron spin resonance.

The conformational transition of the polypeptide chain elongation factor G (EF-G) induced by interaction with guanine nucleotide has been investigated by means of the spin-labeling technique. Various spin-label probes were attached specifically to the sulfhydryl group of the protein that is essential for binding to ribosomes, and the effects of these ligands on the electron spin resonance (ESR) spectra were examined. It was found that the ESR spectra of EF-G labeled with nitroxide maleimide reagents were modified by the addition of various guanine nucleotides such as GDP, GTP and, to a lesser extent, by Gpp(NH)p and Gpp(CH2)p, indicating that conformational changes accompany the binding of nucleotide ligand. However, the ESR spectra of labeled EF-G-GDP and EF-G-GTP were almost identical. On the other hand, when EF-G was labeled with nitroxide iodoacetamide reagents, a clear difference in the ESR spectra of EF-G-GDP and EF-G-GTP derivatives was observed. In this case, the spectral shape of the spin-labeled EF-G in the presence of GTP or its analogs, Gpp(NH)p or Gpp(CH2)p, was quite similar to that of free, unliganded EF-G derivative. These results, together with those previously obtained using hydrophobic probes (Arai, Arai, & Kaziro (1975) J. Biochem. 78, 243-246) demonstrate the existence of an EF-G-guanine nucleotide binary complex. They also indicate that there is a substantial difference in conformation between free EF-G, EF-G-GDP, and EF-G-GTP near the active site essential for interaction with ribosomes.     

Dipsticking the major groove of DNA with enzymatically incorporated spin-labeled deoxyuridines by electron spin resonance spectroscopy

Site-specifically spin-labeled deoxyuridine triphosphates with tethers of different lengths were synthesized and then enzymatically incorporated with terminal transferase to form a spin-labeled poly(dT) copolymer. The spin-labeled copolymers were annealed with poly(dA) to form a duplex, which was analyzed by electron spin resonance spectroscopy in a solution of low ionic strength. The spin labels are attached in position 5 of the deoxyuridine and protrude into the major groove. Based on the correlation between tether length of the spin label and the electron spin resonance lineshape, we show that the depth of the major groove of a DNA in its B-form is about 8 A in solution, which is in good agreement with X-ray fiber studies. We also conclude, based on electron spin resonance lineshape simulation data, that the correlation time of the bases in a DNA duplex is of the order of nanoseconds.     

Structure of spin-labeled methylmethanethiolsulfonate in solution and bound to TEM-1 beta-lactamase determined by electron nuclear double resonance spectroscopy.

Site-directed spin-labeling of proteins whereby the spin-label methyl 3-(2,2,5,5-tetramethyl-1-oxypyrrolinyl)methanethiolsulfonate (SLMTS) is reacted with the -SH groups of cysteinyl residues incorporated into a protein by mutagenesis has been successfully applied to investigate secondary structure and conformational transitions of proteins. In these studies, it is expected that the spin-label moiety adopts different conformations dependent on its local environment. To determine the conformation of SLMTS in solution reacted with L-cysteine (SLMTCys) and bound in the active site of the Glu240Cys mutant of TEM-1 beta-lactamase, we have synthesized SLMTS both of natural abundance isotope composition and in site-specifically deuterated forms for electron nuclear double resonance (ENDOR) studies. ENDOR-determined electron-proton distances from the unpaired electron of the nitroxyl group of the spin-label to the methylene and methyl protons of SLMTS showed three conformations of the oxypyrrolinyl ring with respect to rotation around the S-S bond dependent on the solvent dielectric constant. For SLMTCys, two conformations of the molecule were compatible with the ENDOR-determined electron-nucleus distances to the side-chain methylene protons and to H(alpha) and H(beta1,2) of cysteine. To determine SLMTS conformation reacted with the Glu240Cys mutant of TEM-1 beta-lactamase, enzyme was overexpressed in both ordinary and perdeuterated minimal medium. Resonance features of H(alpha) and H(beta1,2) of the Cys240 residue of the mutant and of the side-chain methylene protons within the spin-label moiety yielded electron-proton distances that sterically accommodated the two conformations of free SLMTCys in solution.     

Electron spin resonance melting of chemically spin-labeled nucleic acids.

Conformational transitions of nitroxide labeled and unlabeled nucleic acids were analyzed by esr and uv spectroscopy to evaluate potential perturbation effects caused by chemical modifications of nucleic acids with spin labels. The melting temperature (T_m) determined by uv or esr melting profiles of 2 → 1 or 3 → 1 transitions is similar for labeled and unlabeled polyadenylic acid [(A)_n] and polyuridylic acid [(U)_n] complexes provided spin-labeled (A)_n with a nitroxide to nucleotide ratio of 0.002 is used. Complexes formed with spin-labeled (A)_n of greater spin-labeling extent display a noticeable perturbation of their thermal melting profiles. The studies reconfirm the existence of a low temperature esr transition at about 20 °C with calf thymus and T4 DNA duplexes spin-labeled with a nitroxide to nucleotide ratio of about 0.006. The uv melting profiles of the spin-labeled duplexes reveal no low-temperature discontinuity, but the T_m values reflecting the 2 → 1 transitions were reduced by several degrees versus those of the unlabeled duplexes. Thus, these studies suggest that with homopolymers, chemically modified to a low extent with nitroxides, the monitoring of local conformational transitions of duplexes or triplexes reflect the overall 2 → 1 or 3 → 1 transitions. In the case of the heteropolymers the possibility that the chemical modification is responsible for the low-temperature phenomenon cannot be ruled out.     

Simulation of coherent energy transfer in an alpha-helical peptide by Fermi resonance.

A mechanism by which NH stretching quanta are coherently transported along a chain of hydrogen bonded peptide groups is demonstrated by classical simulation of a section of the alpha-helical peptide poly(L-alanine). Vibrational motion takes place on a complex energy surface constructed from earlier ab initio and empirical surfaces. A speculative hypothesis of the biological role of this mechanism is presented, and the critical parameters governing the dynamics are identified and discussed.     

Organization of designed nanofibrils assembled from alpha-helical peptides as determined by electron microscopy.

Self-assembling peptides present attractive platforms for engineering materials with controlled nanostructures. Recently, an alpha-helical fibril forming peptide (alphaFFP) was designed that self-assembles into nanofibrils at acid pH. Circular dichroism spectroscopy, electron-microscopy and x-ray fibre diffraction data showed that the most likely structure of alphaFFP fibrils is a five-stranded coiled coil rope. In the present study, scanning transmission electron microscopy (STEM) was used to improve our understanding of the alphaFFP fibril structure. The measurements of fibril mass per length suggest that there are ten alpha-helices in transverse sections of the fibrils. Based on the known data, it is proposed that a predominant fibrillar structure of alphaFFP is a dimer of alpha-helical five stranded protofilaments wrapped around a common axis. It is shown that these structures have an axial dimension of 58 +/- 16 nm and a width of 4 +/- 1 nm. A small number of thin fibrils is also observed in the negative stained preparation and STEM images. The thin fibrils may correspond to the single protofilament.     

Differential effect of lipid peroxidation on membrane fluidity as determined by electron spin resonance probes

The effect of lipid peroxidation on membrane fluidity was examined in sonicated soybean phospholipid vesicles. Following iron/ascorbate dependent peroxidation, the vesicles were labeled with a series of doxyl stearate spin probes which differed in the site of attachment of the nitroxide free radical to the fatty acid. Comparison of motional and partitioning parameters derived from electron spin resonance spectra of the probes indicated that the membranes were less fluid following peroxidation. However, the magnitude of the fluidity decrease was markedly dependent on the intramembrane location, as well as on the extent of lipid peroxidation. The effect of lipid peroxidation on fluidity was maximal in the membrane microenvironment sampled by 12-doxyl stearate, whereas other regions of the bilayer were less affected. These findings indicate that lipid peroxidation leads to an alteration of the transbilayer fluidity gradient.     

Membrane location of apocytochrome c and cytochrome c determined from lipid-protein spin exchange interactions by continuous wave saturation electron spin resonance.

Apocytochrome c derived from horse heart cytochrome c was spin-labeled on the cysteine residue at position 14 or 17 in the N-terminal region of the primary sequence, and cytochrome c from yeast was spin-labeled on the single cysteine residue at sequence position 102 in the C-terminal region. The spin-labeled apocytochrome c and cytochrome c were bound to fluid bilayers composed of different negatively charged phospholipids that also contained phospholipid probes that were spin-labeled either in the headgroup or at different positions in the sn-2 acyl chain. The location of the spin-labeled cysteine residues on the lipid-bound proteins was determined relative to the spin-label positions in the different spin-labeled phospholipids by the influence of spin-spin interactions on the microwave saturation properties of the spin-label electron spin resonance spectra. The enhanced spin relaxation observed in the doubly labeled systems arises from Heisenberg spin exchange, which is determined by the accessibility of the spin-label group on the protein to that on the lipid. It is found that the labeled cysteine groups in horse heart apocytochrome c are located closest to the 14-C atom of the lipid acyl chain when the protein is bound to dimyristoyl- or dioleoyl-phosphatidylglycerol, and to that of the 5-C atom when the protein is bound to a dimyristoylphosphatidylglycerol/dimyristoylphosphatidylcholine (15:85 mol/mol mixture. On binding to dioleoylphosphatidylglycerol, the labeled cysteine residue in yeast cytochrome c is located closest to the phospholipid headgroups but possibly between the polar group region and the 5-C atom of the acyl chains. These data determine the extent to which the different regions of the proteins are able to penetrate negatively charged phospholipid bilayers.     

Dynamics and ordering in a spin-labeled oligonucleotide observed by 220 GHz electron paramagnetic resonance

The dynamics of a newly synthesized cytosine spin-label and the spin-labeled pentamer TTC*TT have been observed by high-frequency (220 GHz) electron paramagnetic resonance (EPR) in aqueous solution at ambient temperature using only nanomolar amounts of spin-label. Temperature studies were carried out for both labeled species in buffer containing glycerol. The motion of the spin-labeled monomer could be fitted using a model of fully anisotropic rotation (FAR) over the entire temperature range studied. In the single-stranded pentamer, the high-field spectra are best interpreted using a model of microscopic ordering with macroscopic disorder (MOMD) with the probe in a highly nonpolar environment. The observed local order parameters of 0.60-0.70 suggest a micelle-like structure in which the label is tightly packed with the hydrophobic bases. These preliminary studies illustrate how the excellent orientation selectivity of high-field EPR provides new dynamic information about local base motions in DNA, and also how high-field EPR of spin-labels allows one to discriminate accurately between the effects of local versus global motions in spin-labeled macromolecules.     

Superoxide formation in spinach chloroplasts: electron spin resonance detection by spin trapping.

The new technique of spin trapping has been applied to a biological system for the first time. The light induced generation of O₂^? by chloroplasts in the presence of oxygen has been shown by the production of the O₂^? adduct of the spin trap 5,5-dimethyl-1-pyrroline-1-oxide. The O₂^? adduct was detected by electron spin resonance spectroscopy. Methyl viologen enhanced the production of the O₂^? adduct thus providing support for the hypothes is that methyl viologen accepts electrons from the primary acceptor of photosystem I and subsequently reduces O₂ to O₂^?.     

Binding of spin-labeled carboxyatractylate to mitochondrial adenosine 5'-diphosphate/adenosine 5'-triphosphate carrier as studied by electron spin resonance

The spin-label 2,2,5,5-tetramethyl-1-oxy-3-pyrroline-3-carboxylic acid was attached to the inhibitor carboxyatractylate of the mitochondrial ADP/ATP carrier. Being closely linked to the inhibitor, the spin-label should reflect the mobility of the carboxyatractylate. When bound to the carrier in mitochondria, spin-labeled carboxyatractylate reveals a most unusual hyperfine splitting of 72 G. A second spectral component with a hyperfine splitting of 62 G is also mainly due to carrier-bound inhibitor. A similar spectrum with somewhat reduced hyperfine splitting was observed with the detergent-solubilized protein, whereas reincorporation into phospholipid membranes yielded almost the same spectra as in mitochondria. The carrier-bound spin-label is concluded to be highly immobilized. The less immobilized spectral component is discussed in terms of strongly anisotropic label motion. In addition, the unusual splitting is interpreted to indicate the highly polar environment of the nitroxide. The interpretations are supported by the temperature dependence, which indicates a reversible progressive spin-label mobilization up to 50 degrees C. Membrane-impermeable reducing agents showed that the spin-label is easily accessible from the aqueous phase.