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Journal of the American Chemical Society 01/2002; 123(50):12742-3. · 9.91 Impact Factor
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ABSTRACT: We report the application of our newly developed dielectric resonator-based flow and stopped-flow kinetic EPR systematically to probe protein folding in yeast iso-1-cytochrome c at cysteine-directed spin-labeled locations. The locations studied have not been previously directly probed by other techniques, and we observe them on a time scale stretching from 50 micros to seconds. On the basis of crystal structure and homology information, the following mutation-tolerant, externally located cysteine labeling sites were chosen (in helices, T8C, E66C, and N92C; in loops, E21C, V28C, H39C, D50C, and K79C), and labeling at these sites was not destabilizing. Dilution of denaturant was used to induce folding and thereby to cause a change in the spin label EPR signal as folding altered the motion of the spin label. Under folding conditions, including the presence of imidazole to eliminate kinetic trapping due to heme misligation, a phase of folding on the 20-30 ms time scale was found. This phase occurred not only at the T8C and N92C labeling sites in the N- and C-terminal helices, where such a phase has been associated with folding in these helices, but overall at labeling sites throughout the protein. In the absence of imidazole the 20-30 ms phase disappeared, and another phase having the time scale of 1 s appeared throughout the protein. There was evidence under all conditions for a burst phase on a scale of less than several milliseconds which occurred at labeling positions V28C, H39C, D50C, E66C, and K79C in the middle of the protein sequence. At spin-labeled D50C rapid-mix flow EPR indicated a very short approximately 50 micros phase possibly associated with the prefolding or compaction of the loop to which D50 belongs. Spin labels have been criticized as perturbing the phenomena which they measure, but our spin labeling strategy has reported common kinetic themes and not perturbed, disconnected kinetic events.
Biochemistry 01/2002; 40(51):15846-55. · 3.42 Impact Factor
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ABSTRACT: We have developed a variable velocity, rapid-mix, continuous-flow method for observing and delineating kinetics by dielectric resonator-based electron paramagnetic resonance (EPR). The technology opens a new facet for kinetic study of radicals in liquid at submillisecond time resolution. The EPR system (after Sienkiewicz, A., K. Qu, and C. P. Scholes. 1994. Rev. Sci. Instrum. 65:68-74) accommodated a miniature quartz capillary mixer with an approximately 0.5 microliter delivery volume to the midpoint of the EPR-active zone. The flow velocity was varied in a preprogrammed manner, giving a minimum delivery time of approximately 150 microseconds. The mixing was efficient, and we constructed kinetics in the 0.15-2. 1-ms time range by plotting the continuous wave EPR signal taken during flow versus the reciprocal of flow velocity. We followed the refolding kinetics of iso-1-cytochrome c spin-labeled at Cysteine 102. At 20 degrees C, upon dilution of guanidinium hydrochloride denaturant, a fast phase of refolding was resolved with an exponential time constant of 0.12 ms, which was consistent with the "burst" phase observed by optically detected flow techniques. At 7 degrees C the kinetic refolding time of this phase increased to 0.5 ms.
Biophysical Journal 06/2000; 78(5):2702-8. · 3.65 Impact Factor
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ABSTRACT: We present a novel dielectric resonator (DR)-based resonant structure that accommodates aqueous sample capillaries in orientations that are either parallel (i.e., side-access) or perpendicular to the direction of an external (Zeeman) magnetic field, B(0). The resonant structure consists of two commercially available X-band DRs that are separated by a Rexolite spacer and resonate in the fundamental TE(01delta) mode. The separator between the DRs is used to tune the resonator to the desired frequency and, by appropriately drilled sample holes, to provide access for longitudinal samples, notably capillaries containing oriented, spin-labeled muscle fibers. In contrast to the topologically similar cylindrical TE(011) cavity, the DR-based structure has distinct microwave properties that favor its use for parallel orientation of lossy aqueous samples. For perpendicular orientation of a dilute (6.25 microM) aqueous solution of IASL spin label, the S/N ratio was at least one order of magnitude better for the side-access DR-based structure than for a standard TE(102) cavity. EPR spectra acquired for maleimide spin-labeled myosin filaments also revealed ca. 10 times better S/N ratio than those obtained with a standard TE(102) cavity. For the side-access DR with sample capillaries oriented either parallel or perpendicular to the external magnetic field, the Q- and filling factors are in good agreement with the theoretical estimates derived from the distribution of magnetic (H(1)) and electric (E(1)) components.
Journal of Magnetic Resonance 04/2000; 143(1):144-52. · 2.14 Impact Factor
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ABSTRACT: Electron nuclear double resonance (ENDOR) was performed on the protein-bound, stabilized, high-affinity ubisemiquinone radical, QH*-, of bo3 quinol oxidase to determine its electronic spin distribution and to probe its interaction with its surroundings. Until this present work, such ENDOR studies of protein-stabilized ubisemiquinone centers have only been done on photosynthetic reaction centers whose function is to reduce a ubiquinol pool. In contrast, QH*- serves to oxidize a ubiquinol pool in the course of electron transfer from the ubiquinol pool to the oxygen-consuming center of terminal bo3 oxidase. As documented by large hyperfine couplings (>10 MHz) to nonexchangeable protons on the QH*- ubisemiquinone ring, we provide evidence for an electronic distribution on QH*- that is different from that of the semiquinones of reaction centers. Since the ubisemiquinone itself is physically nearly identical in both QH*- and the bacterial photosynthetic reaction centers, this electronic difference is evidently a function of the local protein environment. Interaction of QH*- with this local protein environment was explicitly shown by exchangeable deuteron ENDOR that implied hydrogen bonding to the quinone and by weak proton hyperfine couplings to the local protein matrix.
Biochemistry 03/2000; 39(11):3169-75. · 3.42 Impact Factor
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ABSTRACT: We report methodology which combines recently developed dielectric resonator-based, rapid-mix, stopped-flow EPR (appropriate for small, aqueous, lossy samples) with rapid scanning of the external (Zeeman) magnetic field where the scanning is preprogrammed to occur at selected times after the start of flow. This methodology gave spectroscopic information complementary to that obtained by stopped-flow EPR at single fields, and with low reactant usage, it yielded more graphic insight into the time evolution of radical and spin-labeled species. We first used the ascorbyl radical as a test system where rapid scans triggered after flow was stopped provided "snapshots" of simultaneously evolving and interacting radical species. We monitored ascorbyl radical populations either as brought on by biologically damaging peroxynitrite oxidant or as chemically and kinetically interacting with a spectroscopically overlapping nitroxide radical. In a different biophysical application, where a spin-label lineshape reflected rapidly changing molecular dynamics of folding spin-labeled protein, rapid scan spectra were taken during flow with different flow rates and correspondingly different times after the mixing-induced inception of protein folding. This flow/rapid scan method is a means for monitoring early immobilization of the spin probe in the course of the folding process.
Journal of Magnetic Resonance 03/1999; 136(2):137-42. · 2.14 Impact Factor
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ABSTRACT: We report the development of a high-yield heterologous expression system for the copper-containing nitrite reductase from a denitrifying variant of Rhodobacter sphaeroides. Typical yields of wild-type protein are 20 mg L-1, which can be fully loaded with copper. Nitrite reductase contains an unusual blue-green Type 1 copper center with a redox/electron transfer function and a nearby Type 2 center where nitrite binds and is reduced to nitric oxide. The wild-type enzyme was characterized by: (1) its blue-green Type 1 optical spectrum; (2) its EPR spectrum showing rhombic character to its Type 1 center and nitrite perturbation to its Type 2 center; (3) its 247-mV Type 1 midpoint potential which is low relative to other Type 1 centers; and (4) its kinetics as measured by both steady-state and stopped-flow methods. The Type 2 copper reduction potential as monitored by EPR in the absence of nitrite was below 200 mV so that reduction of the Type 2 center by the Type 1 center in the absence of nitrite is not energetically favored. The mutation M182T in which the methionine ligand of Type 1 copper was changed to a threonine resulted in a blue rather than blue-green Type 1 center, a midpoint potential that increased by more than 100 mV above that of the wild-type Type 1 center, and a somewhat reduced nitrite reductase activity. The blue color and midpoint potential of M182T are reminiscent of plastocyanin, but the Type 1 cupric HOMO ground-state electronic g value and copper hyperfine properties of M182T (as well as cysteine and histidine ENDOR hyperfine properties; see next paper) were unchanged from those of the blue-green native Type 1 center. His287 is a residue in the Type 2 region whose imidazole ring was thought to hydrogen bond to the Type 2 axial ligand but not directly to Type 2 copper. The mutation H287E resulted in a 100-fold loss of enzyme activity and a Type 2 EPR spectrum (as well as ENDOR spectra; see next paper) which were no longer sensitive to the presence of nitrite.
Biochemistry 05/1998; 37(17):6086-94. · 3.42 Impact Factor
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ABSTRACT: Q-band ENDOR elucidated proton and nitrogen hyperfine features to provide spin density information at ligands of blue-green Type 1 and catalytic Type 2 copper centers in nitrite reductase. The blue-green Type 1 center of nitrite reductase has a redox, electron-transfer role, and compared to the blue center of plastocyanin, it has the following structural differences: a shortened Cu-Smet bond length, a longer Cu-Scys bond length, and altered ligand-copper-ligand bond angles (Adman, E. T., Godden, J. W., and Turley, S. (1995) J. Biol. Chem. 270, 27458-27474). The hyperfine couplings of the two Type 1 histidine (N delta) ligands showed a larger percentage difference from each other in electron spin density than previously reported for other blue Type 1 proteins, while the cysteine beta-proton hyperfine couplings, a measure of unpaired p pi spin density on the liganding cysteine sulfur, showed a smaller electron spin density. A mutation of the Type 1 center, M182T, having the copper-liganding Met182 transformed to Thr182, caused the center to revert to an optically "blue" center, raised its redox potential by approximately 100 mV, and led to the loss of activity (prior paper). Surprisingly, in M182T there was no change from native Type 1 copper either in the histidine or cysteine hyperfine couplings or in g values and Cu nuclear hyperfine couplings. The conclusion is that the optical and redox alterations due to changed Type 1 methionine ligation need not be concurrent with electron spin delocalization changes in the HOMO as reported from its essential cysteine and histidines. A detailed picture of the nitrogen couplings from the three histidine (N epsilon) ligands of the Type 2 center indicated a substantial ( approximately 200%) electronic hyperfine inequivalence of one of the histidine nitrogens from the other two within the Type 2 HOMO and thus provided evidence for electronic distortion of the Type 2 site. In the presence of the nitrite substrate, hyperfine couplings of all histidines diminished. We suggest that this nitrite-induced decreased covalency would correlate with an increased Type 2 redox potential to assist electron transfer to the Type 2 center. Dipole-coupled, angle-selected exchangeable proton features, observed over a range of g values, predicted a ligand-water proton distance of 2.80 A from copper, and these water protons were eliminated by nitrite. His287 is not a Type 2 ligand but is positioned to perturb an axial water or a nitrite of Type 2 copper. In the presence of nitrite the mutant H287E showed no evidence for the loss of water protons and no diminished ligand histidine covalency. H287E has vastly diminished activity (prior paper), and the ENDOR information is that NO2- does not bind to Type 2 copper of H287E. In summary, the electronic information from this study of native and suitably chosen mutants provided a test of the highest occupied molecular orbital (HOMO) wave function at Type 1 and Type 2 coppers and an intimate electronic insight into functional enzymatic properties.
Biochemistry 05/1998; 37(17):6095-105. · 3.42 Impact Factor
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ABSTRACT: The kinetics of chemically induced folding and unfolding processes in spin-labeled yeast iso-1-cytochrome c were measured by stopped-flow electron paramagnetic resonance (EPR). Stopped-flow EPR, based on a new dielectric resonator structure [Sienkiewicz, A., Qu, K., & Scholes, C. P. (1994) Rev. Sci. Instrum. 65, 68-74], gives a new temporal component to probing nanosecond molecular tumbling motions that are modulated by macromolecular processes requiring time resolution of milliseconds to seconds. The stopped-flow EPR technique presented in this work is a kinetic technique that has not been previously used with such a time resolution on spin-labeled systems, and it has the potential for application to numerous spin-labeled sites in this and other proteins. The cysteine-specific spin-label, methanethiosulfonate spin-label (MTSSL), was attached to yeast iso-1-cytochrome c at the single naturally occurring cysteine102, and the emphasis for this work was on this disulfide-attached spin-labeled prototype. This probe has the advantage of reflecting the protein tertiary fold, as shown by recent, systematic site-directed spin labeling of T4 lysozyme [Mchaourab, H. S. Lietzow, M. A., Hideg, K., & Hubbell, W. L. (1996) Biochemistry 35, 7692-7704], and protein backbone dynamics, as also shown by model peptide studies [Todd, A. P., & Millhauser, G. L. (1991) Biochemistry 30, 5515-5523]. The C-terminal cytochrome c helix where the label is attached is thought to be critical in the initial steps of protein folding and unfolding. Stopped-flow EPR resolved the monoexponential, guanidinium-induced unfolding process at pH 6.5 with an approximately 20 ms time constant; this experiment required less than 150 microL of 80 microM spin-labeled protein. We observed an approximately 50-fold decrease of this unfolding time from the 1 s range to the 20 ms time range as the guanidinium denaturant concentration was increased from 0.6 to 2.0 M. The more complex refolding kinetics of our labeled cytochrome were studied by stopped-flow EPR at pH 5.0 and 6.5. The spin probe showed a fast kinetic process compatible with the time range over which hydrogen/deuterium amide protection indicates helix formation; this process was monoexponential at pH 5.0. At pH 6.5, there was evidence of an additional slower kinetic phase resolved by stopped-flow EPR and by heme-ligation-sensitive UV-Vis that indicated a slower folding where heme misligation may be involved. Since the disulfide-attached probe has reported folding and backbone dynamics in other systems, the implication is that our kinetic experiments were directly sensing events of the C-terminal helix formation and possibly the N- and C-terminal helical interaction. The cysteine-labeled protein was also studied under equilibrium conditions to characterize probe mobility and the effect of the probe on protein thermodynamics. The difference in spin probe mobility between folded and denatured protein was marked, and in the folded protein, the motion of the probe was anisotropically restricted. The motion of the attached nitroxide in the folded protein appears to be restricted about the carbon and sulfur bonds which tether it to the cysteine. The original point of cysteine sulfur attachment is approximately 11 A from the heme iron within the C-terminal helix near its interface with the N-terminal helix, but the low-temperature EPR spin probe line width showed that the probe lies more distant (> 15 A) from the heme iron. By all physical evidence, the protein labeled at cysteine102 folded, but the spin probe in this prototype system perturbed packing which lowered the thermal melting temperature, the free energy of folding, the guanidinium concentration at the midpoint of the unfolding transition, the m parameter of the denaturant, and the helical CD signature. This study prepares the way for study of protein folding/unfolding kinetics using EPR spectroscopy of spin-labels placed at specific cysteine-mutated sites within
Biochemistry 04/1997; 36(10):2884-97. · 3.42 Impact Factor
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ABSTRACT: A new approximate method for predicting the resonant frequencies and for solving the field distribution problem of a cylindrical dielectric resonator (DR) is developed. The model proposed in this paper bridges the gap between rigorous and accurate finite-element or Green function-based numerical methods on the one hand and on the other hand, simple approximate solutions in which the field distribution can be described analytically, but the resulting frequency is accurate within a few percent only. In the method described here, the approximate solution for the microwave field distribution is modified by substituting different values of the radial separation constants inside and outside of the diskshaped DR. The model is generalized for the double-stacked DR structure and enables one to introduce corrections that take into account the presence of the shielding walls and of the cylindrical sample hole. Good agreement is found between experimental and calculated results for both the single and double-stacked structures that are designed around commercially available X-band DRs (9-10 GHz). For the resonant frequency of the lowest transverse-electric TEzero1 delta mode that is commonly used for EPR measurements, the accuracy of the method is better than 1%. Experimentally measured resonator filling factors are also in good agreement with those theoretically estimated. Both the theory and the experimental results suggest that the double-stacked DR structure with finite spacing between the ceramic cylinders is the most suitable for EPR measurements of long lossy samples.
Journal of Magnetic Resonance 02/1997; 124(1):87-96. · 2.14 Impact Factor
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ABSTRACT: The binding of endonuclease III from Escherichia coli to damaged DNA has been studied using gel shift and footprinting assays. Oligonucleotides containing a reduced apyrimidinic (AP) site were used since reduction of the AP site blocks the beta-elimination reaction catalyzed by the enzyme and yields a noncleavable substrate. The Kobs for a 13-mer carrying a centrally located reduced AP site is (2 x 10(6)-(2 x 10(7) M-1, while the Kobs for a 13-mer with no damage is (4.5 x 10(3)-(3.2 x 10(4) M-1 (approximately a 500-fold difference). Larger oligonucleotides would not enter a gel when endonuclease III was bound so that binding constants to oligonucleotides longer than 13 base pairs could not be determined directly. Competition assays suggest that the Kobs measured for both damaged and undamaged 13-mers is a minimum value and that the Kobs for larger oligonucleotides could be an order of magnitude greater. Fluorescence quenching on related 19-mers yielded a specific binding constant for the 19-mer carrying a centrally located reduced AP site for 4 x 10(7) M-1 and a nonspecific binding constant to an undamaged 19-mer of approximately 10(5) M-1 [Xing, D., Dorr, R., Cunningham, R. P., & Scholes, C. P. (1995) Biochemistry 34, 2537-2544]. Several footprinting reagents were used to determine the size and location of the endonuclease III binding site on damaged oligonucleotides.(ABSTRACT TRUNCATED AT 250 WORDS)
Biochemistry 03/1995; 34(8):2528-36. · 3.42 Impact Factor
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ABSTRACT: We have measured the fluorescence of the DNA repair enzyme endonuclease III to discover perturbation to its tryptophans by undamaged DNA and AP (apyrimidinic or apurinic) DNA and to estimate binding affinity for intact and AP DNAs. Endonuclease III has two tryptophans, Trp132 in a helix-hairpin-helix region of possible flexibility near the active site for AP lyase activity and Trp178 in the domain containing the iron-sulfur center of endonuclease III; Trp132 is the more solvent-accessible tryptophan [Kuo, C.-F., McRee, D. E., Fisher, C. L., O'Handley, S. F., & Cunningham, R. P. (1992) Science 258, 434-440]. The fluorescence emission peak wavelength near 350 nm (excitation at 290 nm) indicated an exposure of the fluorescing tryptophans to a polar environment. Quenching of tryptophan fluorescence by iodide demonstrated that there are indeed two tryptophans which are differently accessible to anionic quencher. Significant (approximately 60%) fluorescence quenching occurred when endonuclease III was titrated with high molecular weight duplex undamaged poly(dAdT). The apparent second-order nonspecific binding constant to poly(dAdT) was 4 x 10(7) M-1, and there were approximately 12 base pairs per endonuclease III binding site for binding to poly(dAdT). This nonspecific binding to duplex DNA had ionic character, and there was no fluorescence quenching brought on by single-stranded DNA. A comparison between fluorescence quenching titrations of high molecular weight duplex DNA and undamaged duplex 19-mer oligonucleotide showed that the binding constant to the high molecular weight DNA was approximately 400-fold larger than to the undamaged 19-mer.(ABSTRACT TRUNCATED AT 250 WORDS)
Biochemistry 03/1995; 34(8):2537-44. · 3.42 Impact Factor
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ABSTRACT: Electron nuclear double resonance (ENDOR) and the related pulse technique of pulse field sweep EPR (PFSEPR) were used to probe the site I environment of Mn2+ in the oxalate-ATP complex of pyruvate kinase. Assignment of features and an estimate of hyperfine couplings have shown proximity of protons to the metal ions through their dipolar interaction and proximity of 31P and 17O because of a contact interaction from direct Mn(2+)-ligand covalent spin transfer. Since Mn2+ is a spin5/2 ion whose Ms = +/- 1/2, +/- 3/2, and +/- 5/2 electron spin states can all contribute to EPR and ENDOR, we have developed experimental and theoretical strategies for elucidating hyperfine couplings to the Mn2+ electron spin states. Solvent-exchangeable proton ENDOR features were evident with couplings very similar to the hyperfine couplings of H2O in [Mn(H2O)6]2+. ENDOR of exchangeable, more distant protons originated from a dipolar coupling such as could be expected from protons residing 5.5 A from Mn2+ and hydrogen-bonded to a nonliganding oxygen or nitrogen. Nonexchangeable proton ENDOR features indicated dipolar coupling to proton(s) from the protein residing at approximately 4.5 A from the Mn2+. The approximately 4-MHz 31P phosphate hyperfine couplings in Mn(II)-nucleotide models and in pyruvate kinase were similar, but a detailed ENDOR and PFSEPR comparison revealed that the hyperfine coupling to the ATP gamma-phosphate in pyruvate kinase was approximately 10% less than coupling to phosphates of Mn(II)-nucleotides. [In pyruvate kinase only the gamma-phosphate has been shown to bind to Mn2+ at site I (Lodato & Reed, 1987).](ABSTRACT TRUNCATED AT 250 WORDS)
Biochemistry 08/1993; 32(30):7799-810. · 3.42 Impact Factor
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ABSTRACT: This work broadens the scope and improves the time resolution of spin-probe oximetry, a technique in which small nitroxide spin probes detect oxygen consumption via change in their relaxation properties [Froncisz, W., Lai, C.-S., & Hyde, J. S. (1985) Proc. Natl. Acad. Sci. U.S.A. 82, 411-415]. For rapid oxygen kinetic studies we combined the methodology of spin-probe oximetry with a recently developed loop-gap resonator, stopped-flow EPR system [Hubbell, W. L., Froncisz, W., & Hyde, J. S. (1987) Rev. Sci. Instrum. 58, 1879-1886]. The technique used microliter volumes of reactant solutions. Enzymatic consumption of oxygen by cytochrome c oxidase in the presence of ferrocytochrome c substrate was followed continuously in time under limited-turnover conditions, where the concentration of oxygen consumed often was comparable to or less than the amount of enzyme present. In detecting less than micromolar oxygen concentration changes, we have achieved a time resolution of the order 30 ms when flow is stopped. Oxygen consumption was followed under two different limited-turnover conditions: In the first, the amount of oxygen consumed was limited by available ferrocytochrome c, and the time course of oxygen consumption and its pH dependence were compared with the optically detected ferrocytochrome c consumption. In the second, the oxygen consumed was ultimately limited by the availability of oxygen itself while ferrocytochrome c was regenerated and remained in excess.(ABSTRACT TRUNCATED AT 250 WORDS)
Biochemistry 02/1992; 31(5):1331-9. · 3.42 Impact Factor
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ABSTRACT: The reaction of ferric cytochrome c peroxidase (CcP) from Saccharomyces cerevisiae with peroxide produces compound I, characterized by both an oxyferryl iron center and a protein-based free radical. The electron paramagnetic resonance (EPR) signal of the CcP compound I radical can be resolved into a broad majority component which accounts for approximately 90% of the spin intensity and a narrow minority component which accounts for approximately 10% of the integrated spin intensity [Hori, H., & Yonetani, T. (1985) J. Biol. Chem. 260, 3549-3555]. It was shown previously that the broad component of the compound I radical signal is eliminated by mutation of Trp-191 to Phe [Scholes, C. P., Liu, Y., Fishel, L. F., Farnum, M. F., Mauro, J. M., & Kraut, J. (1989) Isr. J. Chem. 29, 85-92]. The present work probed the effect of mutations in the vicinity of this residue by EPR and electron-nuclear double resonance (ENDOR). These mutations were obtained from a plasmid-encoded form of S. cerevisiae expressed in Escherichia coli [Fishel, L. A., Villafranca, J. E., Mauro, J. M., & Kraut, J. (1987) Biochemistry 26, 351-360]. The EPR line shape and ENDOR signals of the compound I radical were perturbed only by mutations that alter Trp-191 or residues in its immediate vicinity: namely, Met-230 and Met-231, which have sulfur atoms within 4 A of the indole ring, and Asp-235, which forms a hydrogen bond with the indole nitrogen of Trp-191. Mutations of other potential oxidizable sites (tryptophan, tyrosine, methionine, and cysteine) did not alter the EPR line shapes of the compound I radical, although the integrated spin intensities were weaker in some of these mutants. Mutations at Met-230 and/or -231 perturbed the EPR line shapes of the compound I radical signal but did not eliminate it. ENDOR of these two methionine mutants showed alteration to the hyperfine couplings of several strongly coupled protons, which are characteristic of the majority compound I radical electronic structure, and a change in weaker hyperfine couplings, which suggests a different orientation of the radical with respect to its surroundings in the presence of these methionine mutations. Besides the Trp-191----Phe mutation, only the Asp-235----Asn mutation eliminated the broad component of the compound I signal. Loss of the broad compound I EPR signal coincides with both the loss of the Asp----Trp-191 hydrogen-bonding interaction and alteration of the position of the indole ring of Trp-191.(ABSTRACT TRUNCATED AT 400 WORDS)
Biochemistry 03/1991; 30(7):1986-96. · 3.42 Impact Factor
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ABSTRACT: We present an electron nuclear double resonance (ENDOR) study of the bound Qc.- ubisemiquinone in the mitochondrial quinol cytochrome c reductase complex. An ENDOR probe specifically modified for insertion into our electron paramagnetic resonance cavity was used for this study. We observed strongly hyperfine-coupled protons whose exchangeable nature indicated they were hydrogen-bonded to the quinone oxygen(s). It is thought that such hydrogen bonds are critical in binding the ubiquinone to protein, in stabilizing its semiquinone form, and in modulating the thermodynamic properties of the bound ubiquinone in the mitochondrial quinol cytochrome c reductase complex. Additional ENDOR features were assigned to protons of the quinone ring itself and to weakly coupled protons that may be associated with nearby amino acids. From very weakly hyperfine-coupled, distant, exchangeable protons there was also ENDOR evidence to suggest proximity and accessibility of the ubiquinone site to the solvent.
Biochemistry 08/1990; 29(30):6987-93. · 3.42 Impact Factor
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ABSTRACT: Elemental analyses, Mössbauer, and EPR data are reported to show that endonuclease III of Escherichia coli is an iron-sulfur protein. Mössbauer spectra of protein freshly prepared from E. coli grown on 57Fe-enriched medium demonstrate that the native enzyme contains a single 4Fe-4S cluster in the 2+ oxidation state, with a net spin of zero. Upon treatment with ferricyanide, a fraction (less than 25%) of the clusters is oxidized into a state which yields an EPR spectrum near g = 2.01 typical of a 3Fe-4S cluster. The magnetic field dependence of the linear electric field effect verifies this assignment. Electron spin echo modulation on the g = 2.01 form of the protein in deuterated solvent indicates the presence of exchangeable protons in the vicinity of the 3Fe-4S cluster. The data obtained show that the [4Fe-4S]2+ cluster of the native enzyme is resistant to either oxidation or reduction, although photoreduction elicited a g = 1.94 type EPR signal characteristic of a [4Fe-4S]1+ cluster. These studies show that endonuclease III is unique in being both a DNA repair enzyme and an iron-sulfur protein. The function of the 4Fe-4S cluster remains to be established.
Biochemistry 06/1989; 28(10):4450-5. · 3.42 Impact Factor
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ABSTRACT: We measured an electronic change at cysteine ligand(s) of the CuA2+ center brought on by reduction of other metal centers within cytochrome c oxidase, notably cytochrome a. This change specifically manifested itself as a modification in magnetic hyperfine coupling to the beta-protons of the beta-carbons adjacent to the cysteine sulfur in the CuA2+ coordination sphere. The electron nuclear double resonance ENDOR signals of these beta-protons had previously been assigned through study of selectively deuterated yeast oxidase. In the present study the ENDOR signals of the CuA2+ center were compared from the following forms of oxidase: resting (a3+.CuA2+.a3+3.CuB2+); mixed valence, 2-electron-reduced CO-ligated oxidase (a3+.CuA2+.a2+3CO.CuB+), and a more completely reduced mixed-valence CO-ligated oxidase. In agreement with previous studies on 3-electron-reduced oxidase, the latter more completely reduced oxidase showed cytochrome a preferentially reduced with respect to CuA, implying that the majority of paramagnetic CuA2+ centers had reduced cytochrome a partners. The ENDOR-resolved splitting of the beta-proton hyperfine features substantially decreased in going from the first two more oxidized forms to the more fully reduced latter form. Thus, the electronic structure of the CuA2+ center specifically monitored by hyperfine couplings to cysteine protons changed in response to a reductive event elsewhere in the protein. This structural change may correlate with the anticooperative redox interaction recently reported between cytochrome a and CuA.
Journal of Biological Chemistry 04/1988; 263(8):3588-91. · 4.77 Impact Factor
