Librational motion of an "immobilized" spin label: hemoglobin spin labeled by a maleimide derivative.

The spin label Tempo-maleimide, when "immobilized" in hemoglobin, is shown to exhibit motional fluctuation whose amplitude and/or frequency depend on temperature and solution conditions. These motional fluctuations are observable by several electron spin resonance techniques. For desalted hemoglobin the fluctuations are detectable at approximately -15 degrees C using saturation transfer techniques and at approximately +25 degrees C using line-width measurements of normal absorption spectra. In ammonium sulfate precipitated hemoglobin, however, motional fluctuations are not detectable by either technique up to at least 40 degrees C. The most probable mechanism for spin-label motion appears to be either fluctuations in protein conformation which affect the label binding site or conformational transitions of the nitroxide ring itself. These motional fluctuations are shown to introduce a librational character to the overall label motion during hemoglobin rotational diffusion, with the librational motion significantly affecting the use of spin-label spectral shapes to calculate hemoglobin rotational correlation times.     

Spin-labeling proton NMR study on aromatic amino acid residues in the guanine nucleotide binding site of human c-Ha-ras(1-171) protein

A truncated human c-Ha-ras gene product, ras(1-171) protein, was prepared and chemically modified with maleimide spin-label (MSL). By trypsin digestion of the MSL-labeled ras(1-171) protein, MSL-labeled peptide fragments were isolated and sequenced. The cysteine residue in position 118 of the protein, but not the other cysteine residues, Cys-51 or Cys-80, was found to be specifically labeled by MSL. The ESR spectrum of the MSL-labeled ras(1-171) protein indicates that the MSL group attached to Cys-118 is strongly immobilized. Proton NMR spectra at 400-MHz were measured for this MSL-labeled ras(1-171) protein and also for a control sample of a labeled ras(1-171) protein whose MSL was reduced by sodium ascorbate. In the difference spectra for these two proteins, resonances of protons in the vicinity of the MSL group attached to Cys-118 of the ras(1-171) protein were observed. Thus, the MSL group was found to be in the vicinity of the protein-bound GDP. A phenylalanine residue and two histidine residues, which were characterized by 2D HOHAHA and DQF-COSY spectra, were also found to be in the vicinity of MSL. NOE and pH titration analyses indicate that this phenylalanine residue is close to the bound GDP and one of the two histidine residues. By carboxypeptidase digestion, the two histidine residues near MSL were identified as His-27 and His-94.(ABSTRACT TRUNCATED AT 250 WORDS)     

Flexibility of end-labeled polymers from electron spin resonance line-shape analysis: 3' terminus of transfer ribonucleic acid and 5S ribonucleic acid

Saccharomyces cerevisiae tRNA and 5S RNA, Escherichia coli 5S RNA, and wheat germ 5S RNA have each been specifically spin-labeled at the 3'-terminal ribose to give morpholino-spin-labeled (MSL) RNAs. Enzymatic hydrolysis with pancreatic RNase, followed by anion-exchange chromatography, confirms the site of attachment of the spin-label. Effective rotational correlation times, TB and TC, have been determined from electron spin resonance (ESR) peak heights and widths as a function of temperature for each MSL RNA, and Arrhenius plots of -log T vs. 1/T have been constructed. TC is a measure of internal flexibility at the link between the label and the RNA, while TB is a measure of rotational flexibility of the RNA near the labeled site. Validity of the TB and TC determination has been confirmed from simulation of the experimental EPR spectra by theoretical spectra computed for various attachment geometries and motional rates. Discontinuities in the slope of Arrhenius plots for TB were seen at 34 and 66 degrees C (yeast MSL tRNA), 37 and 60 degrees C (E. coli MSL 5S RNA), 37 and 57 degrees C (yeast MSL 5S RNA), and 36 and 54 degrees C (wheat germ MSL 5S RNA). Temperature-induced hydrolysis of each MSL RNA was less than 5% as determined by gel-filtration chromatography. The melting curves are consistent with a recently proposed universal secondary structural model for prokaryotic and eukaryotic 5S RNA.     

Conformational change in thrombospondin induced by removal of bound Ca2+. A spin label approach

The effect of removal of Ca2+ bound to thrombospondin (TSP) on the protein structure in solution has been investigated using ESR spin-label techniques. A maleimide spin label was selectively attached to the free thiol group presumably near the carboxyl-terminal domain in which Ca2+-binding sites are situated. The ESR spectra of spin-labeled TSP showed that the bound label undergoes a relatively fast rotational motion with an effective rotational correlation time in the nano-second time regimes. Removal of bound Ca2+ in TSP by dialyzing spin-labeled TSP from a Ca2+-containing buffer into an EDTA-containing buffer resulted in an increase in the mobility of the bound label by a factor of 2.3. The data suggest that EDTA chelation of bound Ca2+ in TSP induces a conformational change of TSP at least near the site of spin labeling.     

Structural studies of human IgA1 and IgA2 immunoglobulins labeled with two different spin labels

The spin-label method was used for structural study of different subclasses of human immunoglobulin A. The spin label was incorporated into the protein part, as well as into carbohydrates of the IgA molecules. Well resolved outer wide extrema were characteristic of the ESR spectra of IgA spin-labeled at the protein moiety. ESR spectra of IgA tagged at carbohydrates reflected moderately immobilized rotation of the spin label. Dependencies of the parameters of ESR spectra of spin-labeled IgA1 and IgA2 upon viscosity at constant temperature have been investigated and a quantitative analysis of the isotherms was carried out. Spin-labeled oligosaccharide chains of IgA2 possessed great freedom of rotation. At least some of IgA1 oligosaccharides were closely attached to the protein moiety. Both proteins under study have shown flexible structure. The Fc fragment of IgA1 molecule appeared to have a rigid structure.     

Specific spin-labeling of transfer ribonucleic acid molecules.

The spin labels anhydride (ASL), bromoacetamide (BSL) and carbodiimide (CSL) were used to label selectively tRNAGlu, tRNA fMet and tRNAPhe from E. coli. The preparation and characterization of the sites of labeling of eight new spin-labeled tRNAs are described. The sites of labeling are: s2U using ASL, BSL and CLS and tRNAGlu; s4U using ASL and BSL on tRNAfMet and tRNAPhe; U-37 with CSL on tRNfMet; U-33 with CSL on tRNAPhe. The rare base X at position 47 of tRNAPhe has been acylated with a spin-labeled N-hydroxysuccinimide (HSL). The 3'end of unfractionated tRNA molecules has been chemically modified to a morpholino spin-labeled analogue (MSL). Their respective e.s.r. spectra are reported and discussed.     

Interaction of spin-labeled tryptophan with sickle hemoglobin: probing the microenvironment of the contact sites by spin-probe-spin-label techniques

The spin-labeled tryptophan was used as a structural probe of hemoglobin contact sites. The ESR spectral data indicated that the probe exhibits weak binding to hemoglobin with a dissociation constant of 3.2 · 10⁻⁵ and 4.0 mol bound per hemoglobin tetramer. The spectrum suggested that the bound tryptophan was ‘partially immobilized’ with a correlation time reflecting the environment of the tryptophan binding site of 8.2 ns. The topology of the contact sites was investigated by using dual spin-label methodology in which spin-labeled tryptophan and (²H,¹⁵N) substituted and deuterated maleimide spin label [²H-¹⁵N]MSL covalently-bound to Cys-ß93 residue were used. The ESR spectral data suggested that the tryptophan binding sites were located within 8–10Åof the nitroxide free radical of spin-labeled hemoglobin. The environment of the contact sites is discussed.     

Saturation transfer electron parametric resonance of an indane-dione spin-label. Calibration with hemoglobin and application to myosin rotational dynamics.

We have used a recently synthesized indane-dione spin label (2-[-oxyl-2,2,5,5-tetramethyl-3-pyrrolin-3-yl)methenyl]in dane-1,3-dione (InVSL) to study the rotational dynamics of myosin, with saturation-transfer electron paramagnetic resonance (ST-EPR). To determine effective rotational correlation times (tau effr) from InVSL spectra, reference spectra corresponding to known correlation times (tau r) were obtained from InVSL-hemoglobin undergoing isotropic rotational motion in aqueous glycerol solutions. These spectra were used to generate plots of spectral parameters vs. tau r. These plots should be used to analyze ST-EPR spectra of InVSL bound to other proteins, because the spectra are different from those of tempo-maleimide-spin-labeled hemoglobin, which have been used previously as ST-EPR standards. InVSL was covalently attached to the head (subfragment-1; S1) of myosin. EPR spectra and K/EDTA-ATPase activity showed that 70-95% of the heads were labeled, with > or = 90% of the label bound to either cys 707 (SH1) or cys 697 (SH2). ST-EPR spectra of InVSL-S1 attached to glass beads, bound to actin in myofibrils, or precipitated with ammonium sulfate indicated no submillisecond rotational motion. Therefore, InVSL is rigidly immobilized on the protein so that it reports the global rotation of the myosin head. The ST-EPR spectra of InVSL-myosin monomers and filaments indicated tau effr values of 4 and 13 microseconds, respectively, showing that myosin heads undergo microsecond segmental rotations that are more restricted in filaments than in monomers. The observed tau effr values are longer than those previously obtained with other spin labels bound to myosin heads, probably because InVSL binds more rigidly to the protein and/or with a different orientation. Further EPR studies of InVSL-myosin in solution and in muscle fibers should prove complementary to previous work with other labels.     

Synthesis and application of novel bifunctional spin labels.

The synthesis of new bifunctional spin-labeled cross-linking reagents is described. Covalent attachment to papain was achieved via a thiol-specific thiosulfonate residue and, for the second anchor point, via a nonspecific photoreactive azido function. The thiosulfonate formed a reversible disulfide linkage, which could be cleaved again reductively by dithiothreitol. The spin label, a pyrroline-1-oxyl radical, was highly immobilized after attachment to papain by both functional groups and showed little if any relative motion with respect to the protein.     

Apparent hydrogen bonding by strongly immobilized spin-labels

The hyperfine separations of nitroxide spin-labels which are tightly bound within hemoglobin exhibit a substantial temperature dependence even when the hemoglobin is immobilized by freezing or precipitation. It is shown that NO.--HX hydrogen bond formation by the spin-label within its binding site is a good explanation for the observed temperature dependence. Comparative studies using different hemoglobin derivatives and two different spin-labels suggest that the HX group may be some element of the protein matrix and that this hydrogen bond may be a factor in the stabilization of the label within its binding site. The hyperfine separation of a fatty acid spin probe incorporated into aqueous bilayer dispersons of dipalmitoylphosphatidylcholine also exhibits a temperature dependence at low temperature which is qualitatively similar to that of the spin-labeled hemoglobin systems. Saturation transfer electron paramagnetic resonance measurements indicate that label motion is not the source of this temperature dependence. A hydrogen-bond equilibrium between water molecules and the nitroxide NO. group appears to be a plausible source of the temperature-dependent hyperfine separation in the lipid bilayer system. Small amplitude torsional oscillation or librational motion by the nitroxide may also produce additional changes in the hyperfine separation which are difficult to distinguish from hydrogen-bonding effects under some circumstances. The apparent hydrogen-bond equilibrium exhibits a strong thermal and environmental dependence which may be of importance in a number of biophysical spin-label measurements.     

Interaction of spin-labeled tryptophan with sickle hemoglobin: probing the microenvironment of the contact sites by spin-probe--spin-label techniques

The spin-labeled tryptophan was used as a structural probe of hemoglobin contact sites. The ESR spectral data indicated that the probe exhibits weak binding to hemoglobin with a dissociation constant of 3.2.10(-5) and 4.0 mol bound per hemoglobin tetramer. The spectrum suggested that the bound tryptophan was 'partially immobilized' with a correlation time reflecting the environment of the tryptophan binding site of 8.2 ns. The topology of the contact sites was investigated by using dual spin-label methodology in which spin-labeled tryptophan and (2H,15N) substituted and deuterated maleimide spin label [2H-15N]MSL covalently-bound to Cys-beta 93 residue were used. The ESR spectral data suggested that the tryptophan binding sites were located within 8-10 A of the nitroxide free radical of spin-labeled hemoglobin. The environment of the contact sites is discussed.     

Simulation of nitroxide electron paramagnetic resonance spectra from brownian trajectories and molecular dynamics simulations

A simulated continuous wave electron paramagnetic resonance spectrum of a nitroxide spin label can be obtained from the Fourier transform of a free induction decay. It has been previously shown that the free induction decay can be calculated by solving the time-dependent stochastic Liouville equation for a set of Brownian trajectories defining the rotational dynamics of the label. In this work, a quaternion-based Monte Carlo algorithm has been developed to generate Brownian trajectories describing the global rotational diffusion of a spin-labeled protein. Also, molecular dynamics simulations of two spin-labeled mutants of T4 lysozyme, T4L F153R1, and T4L K65R1 have been used to generate trajectories describing the internal dynamics of the protein and the local dynamics of the spin-label side chain. Trajectories from the molecular dynamics simulations combined with trajectories describing the global rotational diffusion of the protein are used to account for all of the dynamics of a spin-labeled protein. Spectra calculated from these combined trajectories correspond well to the experimental spectra for the buried site T4L F153R1 and the helix surface site T4L K65R1. This work provides a framework to further explore the modeling of the dynamics of the spin-label side chain in the wide variety of labeling environments encountered in site-directed spin labeling studies.     

Molecular origin of electron paramagnetic resonance line shapes on β-barrel membrane proteins: the local solvation environment modulates spin-label configuration

In this work, electron paramagnetic resonance (EPR) spectroscopy and X-ray crystallography were used to examine the origins of EPR line shapes from spin-labels at the protein-lipid interface on the β-barrel membrane protein BtuB. Two atomic-resolution structures were obtained for the methanethiosulfonate spin-label derivatized to cysteines on the membrane-facing surface of BtuB. At one of these sites, position 156, the label side chain resides in a pocket formed by neighboring residues; however, it extends from the protein surface and yields a single-component EPR spectrum in the crystal that results primarily from fast rotation about the fourth and fifth bonds linking the spin-label to the protein backbone. In lipid bilayers, site 156 yields a multicomponent spectrum resulting from different rotameric states of the labeled side chain. Moreover, changes in the lipid environment, such as variations in bilayer thickness, modulate the EPR spectrum by modulating label rotamer populations. At a second site, position 371, the labeled side chain interacts with a pocket on the protein surface, leading to a highly immobilized single-component EPR spectrum that is not sensitive to hydrocarbon thickness. This spectrum is similar to that seen at other sites that are deep in the hydrocarbon, such as position 170. This work indicates that the rotameric states of spin-labels on exposed hydrocarbon sites are sensitive to the environment at the protein-hydrocarbon interface, and that this environment may modulate weak interactions between the labeled side chain and the protein surface. In the case of BtuB, lipid acyl chain packing is not symmetric around the β-barrel, and EPR spectra from labeled hydrocarbon-facing sites in BtuB may reflect this asymmetry. In addition to facilitating the interpretation of EPR spectra of membrane proteins, these results have important implications for the use of long-range distance restraints in protein structure refinement that are obtained from spin-labels.     

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.     

Synthesis of a photoaffinity-spin-labeled derivative of ATP and its first application to F1-ATPase

The synthesis of an ATP derivative is described, in which a spin-label is attached to the 3'-position of the ribose moiety and an azido group to C8 of the adenine ring (SL-N3-ATP). Irradiation of this compound at 350 nm generates a nitrene, which will react with any functional group in its vicinity. SL-N3-ATP exhibits a strongly immobilized ESR spectrum in a complex with F1-ATPase from beef heart mitochondria. It was covalently incorporated into this enzyme. SL-N3-ATP may be employed in ESR investigations under conditions in which non-covalent interactions are too weak for motionally restricted species to be easily observed.     

Synthesis and characterization of a spin-labeled aminoacyl transfer ribonucleic acid

Unfractionated yeast transfer ribonucleic acid (tRNA) was reacted in aqueous acetone solution with the sulfhydryl spin-labeling reagnent, N-(l-oxyl-2,2,5,5-tetramethyl-3-Pyrrolidinyl)iodoacetamide. Whereas tRNA stripped of amino acids reacted only slowly, there were sites on tRNA charged with cysteine which combined rapidly with the reagent. The latter class of spin-label was quickly cleaved from the tRNA upon incubation in mildly alkaline solution (pH 8.0), suggesting that it was attached to the cysteinyl side chains. The paramagnetic resonance spectrum of column-purified spin-labeled cysteinyl tRNA showed that the spin-label was partially immobilized as a result of its interaction with the tRNA. When the tRNA was slowly heated, an abrupt increase occurred in the rotational mobility of the paramagnetic amino-acid side chain.     

Structure and flexibility of plasma fibronectin in solution: electron spin resonance spin-label, circular dichroism, and sedimentation studies

Human plasma fibronectin has been investigated by electron spin resonance (ESR) spin-label methods in conjunction with circular dichroism (CD) and sedimentation techniques to investigate its structure and flexibility in solution. The buried sulfhydryl groups of fibronectin were modified with a maleimide spin-label [Lai, C.-S., & Tooney, N. M. (1984) Arch. Biochem. Biophys. 228, 465-473]. Both conventional and saturation transfer ESR spectra give a rotational correlation time of about (2-3) X 10(-8) s for plasma fibronectin, a value that is at least 40 times faster than the rotational correlation time calculated from the minimal molecular dimensions. This argues that plasma fibronectin is not a compact, globular protein and suggests that the regions of ordered structural domains have a relatively high degree of independent mobility. ESR, CD, and sedimentation measurements showed that many structural features of plasma fibronectin remain unchanged when the pH is decreased from 7.4 to 3.0. On the other hand, ESR results indicate an unfolding of the protein molecule either at pH 11 or in 4 M urea solution. Similarly, the sedimentation coefficient decreases from about 13 to 8.4 S when the pH is raised to 10.8. At pH values above 11, the CD spectrum resembles a random coil; however, some ordered structure is retained either at pH 11 or in 4 M urea. It is likely that the sulfhydryl-containing regions of the molecule are more sensitive to urea or alkali than are portions of the molecule stabilized by intrachain disulfide bonds.(ABSTRACT TRUNCATED AT 250 WORDS)     

Influence of the disulfide bond configuration on the dynamics of the spin label attached to cytochrome c

A series of multi-nanosecond molecular dynamics (MD) simulations of wild-type cytochrome c and its spin-labeled variants with the methanethiosulfonate moiety attached at position C102 were performed (1) to elucidate the effect of the spin probe presence on the protein structure and (2) to describe the structure and dynamics of the spin-label moiety. Comparisons with the reference crystal structure of cytochrome c (PDB entry: 1YCC) indicate that the protein secondary structure is well preserved during simulations of the wild-type cytochrome c but slightly changed in simulations of the cytochrome c labeled at position C102. At the time scale covered in our simulations, the spin label exhibits highly dynamical behavior. The number of observed distinct conformations of the spin label moiety is between 3 and 13. The spin probe was found to form short-lived hydrogen bonds with the protein. Temporary hydrophobic interactions between the probe and the protein were also detected. The MD simulations directly show that the disulfide bond in the tether linking a spin probe with a protein strongly influence the behavior of the nitroxide group. The conformational flexibility and interaction with the protein are different for each of the two low energy conformations of the disulfide bond.     

Location of the Ca(2+)-transport site of Ca(2+)-transporting ATPase of the sarcoplasmic reticulum as determined by analysis of paramagnetic interaction between Gd3+ ions bound at the transport site and membrane-embedded nitroxide spin probes.

Gd3+ ions were bound to the Ca(2+)-transport site of Ca(2+)-transporting ATPase of the sarcoplasmic reticulum (SR-ATPase) and their effect on the ESR spectrum of spin-probes, which were attached to specific sites on SR-ATPase and embedded in the membranous lipid at various depths from the surface of the membrane, was studied. Spin-labeled reagents, 1-oxyl-2,2-dimethyl-oxazolidine derivatives of maleimidoethyl-keto stearate, collectively abbreviated as MSL(m,n) were mainly used for labeling SR-ATPase. They have Cm- and Cn-hydrocarbon chains, respectively, on both sides of the spin label, of which the Cm-hydrocarbon chain is located distal to the carboxyl group of the keto stearate moiety. Paramagnetic interaction between Gd3+ and a spin probe was detected by measuring the decrease in the intensity of the ESR signal of the probe. Displacement of Gd3+ from the Ca(2+)-transport site by Ca2+, which had been confirmed previously by using fluorescently labeled SR-ATPase (described in the preceding article), led to a significant reversal of the paramagnetic effect of Gd3+ on MSL(12,3) and MSL(10,5) attached to SR-ATPase. On the other hand, the effect of Gd3+ was not reversed by Ca2+ when SR-ATPase labeled with MSL(1,14) or a spin-label specific for the cytoplasmic domain was used. These results led us to conclude that the Ca(2+)-transport site of SR-ATPase is located in the membranous region of the molecule, but that the site is not very far from the surface of the membrane of the sarcoplasmic reticulum.