(Received for publication, March 17, 1997, and in revised form, May 14, 1997)
From the Arthur Amos Noyes Laboratory of Chemical
Physics and the § Carl and Winfred Braun Laboratories of
Chemistry and Molecular Biology, California Institute of Technology,
Pasadena, California 91125; the ¶ Department of Microbiology,
Lund University, S-233 62 Lund, Sweden; and the
Molecular
Biological Division, Veterans Administration Medical Center, University
of California at San Francisco, San Francisco, California 94121
Electron paramagnetic resonance (EPR) studies of
succinate:ubiquinone oxidoreductase (SQR) from Paracoccus
denitrificans have been undertaken in the purified and
membrane-bound states. Spectroscopic "signatures" accounting for
the three iron-sulfur clusters (2Fe-2S, 3Fe-4S, and 4Fe-4S), cytochrome
b, flavin, and protein-bound ubisemiquinone radicals have
been obtained in air-oxidized, succinate-reduced, and
dithionite-reduced preparations at 4-10 K. Spectra obtained at 170 K
in the presence of excess succinate showed a signal typical of that of
a flavin radical, but superimposed with another signal. The
superimposed signal originated from two bound ubisemiquinones, as shown
by spectral simulations. Power saturation measurements performed on the
air-oxidized enzyme provided evidence for a weak magnetic dipolar
interaction operating between the oxidized 3Fe-4S cluster and the
oxidized cytochrome b. Power saturation experiments performed on the succinate- and dithionite-reduced forms of the enzyme
demonstrated that the 4Fe-4S cluster is coupled weakly to both the
2Fe-2S and the 3Fe-4S clusters. Quantitative interpretation of these
power saturation experiments has been achieved through redox
calculations. They revealed that a spin-spin interaction between the
reduced 3Fe-4S cluster and the cytochrome b (oxidized) may
also exist. These findings form the first direct EPR evidence for a
close proximity (2 nm) of the high potential 3Fe-4S cluster, situated
in the succinate dehydrogenase part of the enzyme, and the low
potential, low spin b-heme in the membrane anchor of the enzyme.
Succinate:ubiquinone oxidoreductase, SQR,1 is the only membrane-bound enzyme in the tricarboxylic acid cycle. As "complex II," it performs the two-electron oxidation of succinate to produce fumarate, while transferring the electrons to quinone (Q) to yield quinol (QH2). The reverse process is mediated by quinol:fumarate oxidoreductases (QFR), which occur in anaerobic and some facultative organisms. The two enzymes are related and are capable of catalyzing their respective reverse reactions under suitable conditions (1, 2).
SQR contains three or four polypeptides depending on the organism. The largest subunit, a flavoprotein, contains the dicarboxylate binding site and one flavin moiety (FAD); the latter is covalently bound in most cases. The iron-sulfur protein is intermediate in size and contains three iron-sulfur clusters of type 2Fe-2S, 4Fe-4S, and 3Fe-4S, often referred to as S-1, S-2, and S-3, respectively, in the case of SQR. These two hydrophilic subunits protrude into the cytosol (prokaryotic enzyme) or the mitochondrial matrix (eukaryotic enzyme), and together catalyze the succinate dehydrogenase activity of the enzyme. They are anchored to the membrane by one or two hydrophobic quinone polypeptides (QP), which may contain zero, one, or two b-heme(s). These anchoring subunits confer reactivity with the bound Qs; for SQR from bovine heart (3, 4) and a variety of higher plants (5), the existence of two Q sites has been established. SQR from Paracoccus denitrificans contains covalently bound FAD; the membrane anchor consists of two polypeptides with a mono-heme cytochrome b (6). Despite extensive efforts (for reviews see Refs. 1, 2, and 7), the electron-transfer pathway(s) and the mechanism of Q reduction in SQR remain controversial (1, 8, 9).
We chose to study the enzyme from P. denitrificans for the following reasons. The membrane-bound form of the P. denitrificans enzyme in whole cells is characterized by electron paramagnetic resonance (EPR) signals like those observed in mammalian mitochondria (10). P. denitrificans appears to be the closest bacterial homologue to this organelle (11, 12), and its SQR is amenable to molecular genetic techniques. The purification and basic biochemical properties of SQR from this bacterium have also been reported (6).
The air-oxidized, ferricyanide-oxidized, succinate- and dithionite-reduced forms of the enzyme have been investigated by EPR spectroscopy. Spectroscopic "signatures" accounting for each of the redox centers have been obtained at these different levels of reduction of the protein. EPR spectral simulations of the radical signals are consistent with two Q binding sites. An EPR signal characteristic of a reduced 3Fe-4S cluster, has been observed for the first time for SQR or QFR. In addition, we have analyzed quantitatively the power saturation and redox behavior of the S-3 center in the air-oxidized enzyme, and the S-3 and S-1 centers in the succinate-reduced enzyme. Taken together, we conclude that S-3 center and the b-heme are coupled magnetically in their oxidized states, and presumably in their respective reduced and oxidized states, as well.
Centricon ultrafiltration tubes were from Amicon
Inc., Beverly, MA; dodecyl--D-maltoside was from
Anatrace, Maumee, OH; 4-amino-2,2,6,6-tetramethyl-1-piperidinyloxyl, and Sephadex G-50 were purchased from Sigma Chemical Co.; polyethylene glycol tert-octylphenyl ether; Tris, Triton X-100, and
polyoxethylene (9) lauryl ether (Tesit) were purchased from Boehringer
Mannheim (Indianapolis, IN, or Mannheim, Germany); Amberlite XAD-2
adsorbent was from Serva, Heidelberg, Germany. All other reagents were
of analytical reagent grade.
Growth of P. denitrificans (ATCC no. 13543) used for isolation of SQR was performed as described previously (13). Cells were harvested with a continuous flow centrifuge and frozen in liquid nitrogen as 200-g flat packs. Growth conditions for the PD1222/pPSD100 strain containing overproduced (~2-fold) SQR, its construction, and isolation of membranes from it, will be described elsewhere.2
Enzyme PurificationSQR was purified by thawing the stored cell packs using 150-200 g of material each time. The purification procedure was as described previously (6), with modifications similar to those described previously (14, 15). The enzyme was concentrated, and the salt and Triton X-100 concentrations of the final samples were reduced, the latter to ~0.05% (w/v), by repeated exchange in Centricon 100-kDa cutoff concentrators against 100 mM Hepes, pH 7.4. The final yield was 1-2 ml of 50-100 µM SQR. SQR from the PD1222/pPSD100 strain was purified in an identical fashion to that from the ATCC no. 13543 strain. The enzyme was considered sufficiently pure (>90%) for use in our experiments by criteria of optical spectra (negligible absorption due to hemes other than b557) and SDS-polyacrylamide gel electrophoresis (6).
Analytical ProceduresEnzyme concentrations were determined
by measuring the acid-nonextractable FAD content of the samples (16).
Cytochrome b concentrations were determined from dithionite
reduced-minus-oxidized difference spectra in a pyridine hemochrome
assay mixture, using 557-540 = 24.0 mM
1 cm
1 (17). The SQR activity
was measured with a large excess of ubiquinone-2 (Q2; 20 µM) and dichlorophenol-indophenol as the primary and
terminal electron acceptors, respectively (6, 18); activation of the
enzyme was achieved by incubating the enzyme (in Triton X-100) for 20 min at 298 K in 50 mM Tris buffer, 50 mM sodium
succinate, 0.2 mM dodecyl-
-D-maltoside, pH
7.5. Typical turnover numbers (moles of succinate/mol of SQR) of the
purified enzyme at 310 K were 300-350 s
1 based on the
FAD concentrations of the samples (see also Ref. 6). Extraction of the
protein-bound ubiquinone-10 (Q10) was performed according
to the procedure of Redfearn (19). Its concentration was determined
using ubiquinone-6 (Q6) as an internal standard for
analysis by high performance liquid chromatography (275 nm) employing a
C18 reverse-phase column and eluting with a solvent gradient starting at 25:75% water:acetonitrile and finishing at 100%
acetonitrile.
Samples stored at 193 K were thawed
on ice and equilibrated with argon prior to freezing the samples in
liquid nitrogen to remove oxygen from the system. Samples reduced with
excess sodium succinate (35-100 mM, pH 7.4) were incubated
for 45 min at 297-300 K; (sodium) dithionite-reduced samples (10 mM, pH 7.4) were incubated for 5 min at the same
temperature. The succinate concentrations were varied between 35 and
100 mM to yield [succinate]/[SQR] 1300 (E
71 mV, where E denotes solution
potential; see below), for samples with different SQR concentrations;
dithionite-reduced samples may be approximated by E
400 mV. Succinate- and dithionite-reduced PD1222/pPSD100 membranes in
20 mM MOPS, 65 mM Hepes, pH 7.4, were treated
identically, except for the addition of 2 mM KCN (final concentration) to these samples. Ferricyanide-oxidized SQR was obtained
by incubating the sample with excess ferricyanide, which was
subsequently removed by Sephadex G-50 column filtration. Samples, to
which a 3-fold excess of (exogenous) Q2 were added, were
incubated for 5 min at 295 K and subsequently reduced with excess
succinate, as described above. The QP were isolated from
detergent-depleted SQR using perchlorate, essentially as described for
the mammalian enzyme (20). The nonionic detergent Thesit (1.5% w/v)
was removed from the SQR-detergent micelle mixture by adsorption to
Amberlite XAD-2 beads.
EPR spectra were recorded on a Varian E-109
X-band spectrometer equipped with a E-231 TE-102 rectangular cavity,
and interfaced with an IBM personal computer for accumulation and
digitization of the spectra. Sample temperature was controlled by a
variable temperature helium flow cryostat system (Oxford Instruments). Spectral manipulation was performed using the program Labcalc on an IBM
personal computer. Quantitation of the reduced S-1 and S-3 signal
intensities (see Fig. 5) was performed by measuring peak heights (21);
double integration of the digitized first-derivative spectra was
performed in the case of the oxidized S-3 center (see Fig. 4). Spectra
obtained at liquid helium temperatures (4-20 K) were
base-line-corrected by subtracting spectra derived from a buffer-filled
EPR tube under identical conditions. EPR signal line widths are given
as peak-to-trough line widths under nonsaturating conditions. The
combined spin concentrations of the radical signals due to FAD·
and Q·]3 of the
purified preparations (solid lines in Fig. 3, A,
C, and E) have been determined using a
4-amino-2,2,6,6-tetramethyl-1-piperidinyloxyl standard under
nonsaturating conditions.4
EPR acquisition parameters are given in the figure legends; the number
of scans taken per spectrum is one, unless mentioned otherwise.
Computational Procedures
EPR simulations of the composite
FAD·-Q·signal (see Fig. 3) have been carried out using
the program EPR, a modeling approach (F. Neese, University of Konstanz,
Konstanz, Germany) on an IBM-compatible 486:50 MHz computer. The
computer program uses first-order perturbation theory to simulate the
EPR transitions as a function of the magnetic field (or frequency).
This treatment was deemed to be sufficient, as the condition
A0 ge
eB is
fulfilled for radicals; i.e. their hyperfine interactions
are much smaller than their Zeeman interactions. Initial estimates of
the anisotropy (axiality) in the g and hyperfine (A)
matrices corresponding to the strongly coupled nitrogens of the
FAD·, as well as the line widths (x, y,
and z) of the FAD·, were obtained from those reported
previously for flavoproteins. Proton hyperfine interactions and "g
strain" were neglected (22). Initial simulations were generated using
the option "Spectra series," which allows the simulator to test the
effect of a particular EPR parameter on the (simulated) spectrum. When
a satisfactory likening between the simulated and experimental spectrum
was obtained, the g values and spectral weights of the Q· were
"fine-tuned" using the option "Fit" (Simplex algorithm; see
"Results" and the legend of Fig. 3 for further details).
Redox calculations used to estimate the percentage reduction of the
redox centers within SQR in the presence of excess succinate (E
71 mV) and dithionite (E <
400 mV) were programmed in
Mathematica (version 2.2.2) (23); the program is available from Dr.
Chan upon request. The values of the redox midpoint potentials
(Em values) used in the calculations were those
measured for the bovine heart
enzyme,5 unless mentioned
otherwise6:
EmFAD/FAD· = EmFAD·/FADH2 =
71
mV6;
EmS
1ox/S-1red =
14 mV5 (24);
EmS-2ox/S-2red =
260 mV5 (25);
EmS-3ox/S-3red = 60 mV5(26);
EmFe3+/Fe2+ =
175 mV 6;
EmQ/Q· = 30 mV6;
EmQ·/QH2 =
20
mV.6
The half-saturation parameter, P1/2, was obtained from the EPR power-saturation data in Fig. 4A using curves generated in Mathematica (27, 28). The power saturation data in Figs. 4 and 5 were (also) analyzed using nonlinear least-squares regression onto the data of a semiempirical equation7 (see also Table II) (29, 30) using the program Kaleidograph.
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SQR from various eukaryotes and prokaryotes has been characterized by EPR in the membrane-bound and purified states (1). The bovine heart protein has been under intense investigation for many years (1, 2, 7), and should serve as an excellent point of departure for the P. denitrificans enzyme, because of its close evolutionary linkage (11). Also, the amino acid sequence similarity of the flavoprotein and iron-sulfur protein subunits is highly conserved between species (1).
We have focused on three issues in the present study: 1) EPR "fingerprinting" of membrane-bound and purified SQR, 2) investigating the EPR power saturation behaviors of the EPR signals of the iron-sulfur clusters centers in an attempt to derive structural information from their spin-relaxation behavior, and 3) performing redox calculations allowing quantitative interpretation of the experimental results.
Fingerprinting SpectraEPR spectra of "as isolated"
(i.e. air-oxidized), succinate-, and dithionite-reduced
membranes of the SQR overproducing PD1222/pPSD100 strain are shown in
Fig. 1. The spin-states of the redox
centers of the enzyme at the three levels of reduction are given in
Table I. For air-oxidized SQR, the almost
isotropic resonance centered at g = 2.006 with a line width of 2.5 mT (Fig. 1A) is characteristic of a signal arising from the
oxidized S-3 center (see also Fig. 2A) (1, 31, 32). The very
broad trough superimposed onto the S-3 signal (see inset for
absorption signal) forms part of a gy 2.1 component of the
b-heme of SQR. This g value falls within the range of
gy values reported for low spin ferric hemes (33-35), and is
the same as that for the purified enzyme (see below).
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The above assignment to the b-heme was confirmed by the persistence of the signal in the succinate-reduced spectrum (Fig. 1B), as the Em of the cytochrome b of the P. denitrificans enzyme5 is much lower than that of the fumarate:succinate couple at pH 7.4 (5 mV) (36). Therefore, it is not reduced appreciably (~8%; data not shown) by succinate (see also Fig. 2, A and B). The gz component, 3 < gz < 4, was also detectable, though barely (spectral region not shown, but see Fig. 2, A and B, for evidence of this feature). In addition, reduction with succinate elicited an almost axial ferredoxin-like spectrum for the S-1 center with gz = 2.01, gy = 1.92, and gx = 1.91 (Fig. 1B); the g = 1.99 signal is characteristic of the FAD· of SQR (10, 37-39).
Upon addition of dithionite to the sample, broad resonances at g = 2.07 (positive maximum), and 1.86 and 1.77 (negative minima) due to the
S-2 center appeared, superimposed onto those of the S-1 center, but
those due to the FAD· and the b-heme disappeared
(Fig. 1C). Assignment of the former features to the S-2
center was based on the fact that they were not elicited in the
succinate-reduced spectrum, the S-2 center being a low-potential center
(Em = 260 mV in the bovine-heart enzyme) (25).
Also, these signals are of very low intensity in SQR and fumarate
reductase; this low intensity is thought to be due to spin-spin
interactions with the other iron-sulfur clusters (1, 40) (see Fig. 5
for the relevant power saturation experiments).
Fig. 2 depicts spectra recorded on purified SQR. Fig. 2A shows a nearly isotropic (g = 2.008) S-3 resonance (line width, 1.9 mT; see also Ref. 6) observed for the as isolated enzyme. The EPR signal intensities of the ferricyanide-oxidized and as isolated S-3 center were not significantly different; therefore, the 3Fe-4S cluster in as isolated samples of the enzyme was present in its oxidized state. The broad trough was (again) assigned to the gy component of the b-heme (~2.1). The 0-300 mT region of the spectrum (inset) for the as isolated protein shows peaks at g = 5.9 and 4.2, and a very small one at g = 3.6; these features were assigned to high spin ferric hemes (presumably originating from slight contamination with terminal oxidases), adventitious iron, and a gz component due to the b-heme, respectively.
The extent to which g anisotropy could be the cause of the low
intensities of the b-heme gz and gy
components (33, 34) was ascertained by comparing the intensities of the gz components of low spin heme signals from different species.
This effect was excluded because the gz value of the P. denitrificans b-heme is comparable to that of the low potential
b-heme of the bovine heart enzyme (gz = 3.46; Em = 185 mV) (41) and the high potential
b-heme of the Bacillus subtilis
succinate:menaquinone oxidoreductase (gz = 3.68;
Em = 65 mV) (42). To determine whether the virtual
EPR invisibility of the b-heme (gz and gy components) was due to relaxation-enhancement of this metal center by
the S-3 center, or due to an extremely short intrinsic
spin-lattice relaxation time, T1, we prepared
isolated QP. The EPR of the isolated QP (24 µM
b-heme) showed a very small gz = 3.6 signal (spectrum not shown), again in comparison with the gz signals
originating from the bovine heart enzyme and the B. subtilis succinate:menaquinone oxidoreductase, for comparable b-heme
concentrations. Thus, it was concluded that the intrinsic
T1 of the cytochrome is very short.
Succinate-reduced purified SQR (Fig. 2B) gives rise to
resonances at gz = 2.018, gy = 1.920, and gx = 1.910 due to the reduced S-1 center. The gy 2.1 and gz
3.6 components due to the b-heme persist, as
expected. A FAD· signal is observed at g = 1.998. The
"shoulders" at g = 1.990 and 1.980 are attributed to Q·
and scalar coupling of the FAD free radical electron to a strongly coupled nitrogen atom (22), respectively (see below; Fig.
3). The spectral feature due to the
Q· in the membrane-bound enzyme was less readily detected due to the lower signal-to-noise ratio of that spectrum (see Fig.
1B). The inset in Fig. 2B shows a
broad signal at g = 12.6 due to the reduced S-3 center. This
spectral feature is consistent with a
MS = 4 transition within the ST = 2 spin-manifold of the
iron-sulfur cluster (43, 44) (see also "Discussion").
The dithionite-reduced enzyme (Fig. 2C) shows the spectral features expected from reduced centers S-1, at gz = 2.016, gy = 1.922, and gx = 1.910, [see also (6)]; and S-2, at 2.27, 2.07, 2.05 (positive maxima), and 1.86 and 1.78 (negative minima). The g values of the S-1 center are virtually identical to those characterizing the iron-sulfur cluster in the succinate-reduced state of the enzyme (see above; Fig. 2B). This result suggests little or no reorganization of the ligands of the 2Fe-2S cluster upon reduction of the 4Fe-4S cluster. However, the succinate-reduced enzyme yielded ~0.88 spins/molecule compared with 1.00 for the dithionite-reduced sample, as measured from the intensities of the gx-components of the 2Fe-2S cluster in the two samples. The integrated intensities of the resonances in the dithionite-reduced enzyme due to the S-1 and S-2 centers were approximately twice (2.15 ± 0.07; n = 2) that of the S-1 center alone. We take these findings as evidence for the fact that these centers are present in a 1: 1 molar ratio in the purified enzyme. The reduced S-3 center remained EPR-active (g = 12.6) as expected (see Table I) in the dithionite-reduced sample; the g = 12.6 signal has also been observed for the succinate- and dithionite-reduced membranes (spectra not shown).
EPR Spectral Simulations of the Radical SignalsSQR from
bovine-heart (1, 3, 4, 45-47) and a variety of higher plants (5) binds
tightly two Q's, of which the semi-quinone form is stabilized
preferentially. In the bovine-heart enzyme a four-line spectrum is
observed at E 100 mV and T = 10-13 K (1, 46, 47), or
during turnover (100 ms) (3). The spectral features appear to be best
simulated by a dipolar-coupled Q·-Q·signal superimposed
onto that of a non-interacting oxidized S-3 center (3, 45). However,
evidence attesting to the possibility that the oxidized S-3 center
(MS = ±1/2; ground state Kramer's doublet; see
Table I) interacts with the Q· has been provided by EPR
simulation, and the fact that the spectroscopic features disappear
concomitantly with reduction of the S-3 center (3). In our experiments
we observed a signal reminiscent of Q· in the equilibrium
succinate-reduced state of the P. denitrificans enzyme at 4 K (Fig. 2B); however, no observable splittings were present
at this low temperature, as may be expected for the reduced state of
the S-3 center (ST = 2; see Table I). Therefore, we
performed EPR spectral simulations of the g = 2 region of the succinate-reduced enzyme at 170 K (Fig. 3). At this temperature the
resonances due to the S-1 center and the b-heme are
conveniently broadened beyond detection.
We have simulated the experimental composite FAD·-Q·signal to establish whether the P. denitrificans enzyme binds one or two Q·. We have studied three different preparations from two strains. The first preparation (ATCC no. 13453 strain) contained 0.7 bound Q10: FAD (see Fig. 3A); the second (PD1222/pPSD100 strain) contained 0.1 bound Q10: FAD and was supplemented with a 3-fold stoichiometric excess (with respect to the FAD concentration) of exogenous Q2 (see Fig. 3C); the control for this sample was a nonsupplemented sample containing 0.2 Q10: FAD (see Fig. 3E). In the Q2-supplemented preparation, we assume that the binding site(s) (is) are saturated with Q2; in the former the Q10 is substoichiometric with respect to the enzyme, and distributes over the two Q sites (QA and QB; if present) according to their relative affinities (1/Kd values), which are unknown at present.
To achieve our objective of assigning one or two Q sites to the P. denitrificans enzyme, without having an experimental spectrum of the "pure" P. denitrificans FAD·signal (see below), we simulated the composite signal with a FAD· and either one or two superimposed Q·. Evidence for the g = 1.994 spectroscopic feature originating from Q· has come from comparison of the three samples with different Q contents. In accordance with the different Q content of these preparations, the g = 1.994 feature was altered (see legend to Fig. 3, A, C, and E).
We commenced by adjusting/fitting (see "Computational Procedures" for details) the EPR spectral parameters associated with the FAD· and one Q· (Fig. 3, dashed-dotted line) to the experimental FAD·-Q·spectrum (solid line) of the enzyme isolated from the ATCC no. 13543 strain; this simulation was then repeated with two Q· (Fig. 3A, dotted line). The hyperfine (A) constants, g values and line widths characterizing the EPR transitions of the FAD·, and the line widths of the Q·, for which a good fit to the experimental (FAD·-Q·) spectrum was obtained in both cases, were then kept constant (see Fig. 3 legend for their values). Thus, the EPR parameters that best characterized the P. denitrificans FAD· were decided upon and chosen to represent the pure FAD·signal (see inset of Fig. 3A; top right-hand corner). Further refinement (fitting; see "Computational Procedures") of the FAD·-1Q· and FAD·-2Q· simulations involved the g values and weights of the (two) Q·.
It is clear from Fig. 3A that the experimental spectrum of the ATCC no. 13543 strain is rather well simulated using either one or two superimposed Q·, although the FAD·-2Q· simulation appears superior (see e.g. the 329-mT region of the spectrum). However, to circumvent this problem, we subtracted the FAD· simulation from the experimental spectrum and from the FAD·-1Q· and FAD·-2Q· simulations. Thus, this procedure yields the features due to one Q· or two Q· only (see Fig. 3B), allowing us to discriminate more precisely between the FAD·-1Q· and FAD·-2Q· simulations. We conclude that the composite FAD·-Q·signal is best simulated using two Q·. The same procedure was then followed for the enzyme purified from the PD1222/pPSD100 strain in the presence of exogenous Q2 (3-fold excess; Figs. 3C). Again, the simulated spectral features are better for the simulation with two Q· (dotted lines in Fig. 3, C and D). The experimental spectrum (solid line) and simulation (dotted line) for a similar preparation without added Q2 is shown in Fig. 3E. The spectrum obtained on the membrane-bound enzyme (solid line) and its FAD·-2Q· simulation (dotted line) are shown in Fig. 3F.
The FAD· signals with their characteristic "wings," due to the strongly coupled N(5) and N(10) nitrogens (22, 48, 49) are observed in both the purified and membrane-bound preparations (solid lines in Fig. 3A, C, E, and F, respectively). The line width of the FAD· signal of the purified preparation is 1.15 mT. The "extreme shoulders" are separated by 5.4 mT and are due to the molecules with the magnetic field perpendicular to the plane of the FAD ring system. The values of the line width and the separation of the extreme shoulders are suggestive of the "red" (anionic) form of the radical (50). However, it is possible that the spectrum includes a contribution from proton hyperfine interactions (48). A mixed form at pH 7.4 would be consistent with a pKa = 8.0 ± 0.2 for the bovine heart enzyme (49).
Heme and Q Contents of the Purified ProteinThe molar ratio of FAD to b-heme and Q10 in the enzyme purified from membranes of ATCC no. 13543 strain was 1:1.0 ± 0.3:0.9 ± 0.3 (n = 11 and 5, respectively); thus, the preparations contained 0.9 ± 0.4 Q10 per b-heme. The number n represents measurements on different enzyme preparations. However, enzyme purified from membranes of PD1222/pPSD100 strain contained 1:1.3 ± 0.4:0.1 ± 0.1 (n = 5) FAD: b-heme: Q10; or 0.1 ± 0.1 Q10 per b-heme. The reason for the difference in the Q10 contents of SQR purified from the two strains is unknown at present.
EPR Power Saturation Behavior of the S-3 Center in the Air-oxidized EnzymeThe power saturation behavior of the (air) oxidized 3Fe-4S cluster has been measured in an attempt to deduce whether a dipolar interaction exists between this iron-sulfur cluster and the b-heme. Such magnetic coupling had been postulated (7), but EPR evidence for this interaction has been lacking.
Fig. 4A shows the EPR power
saturation behavior of the S-3 signal in the air-oxidized enzyme. In
this state of the enzyme, the cytochrome b is the only other
center that is paramagnetic (see Table I). The
P1/2 values obtained from the computer-generated curves (see "Experimental Procedures") were 0.02, 32, and ~200 mW
for the data recorded at 4, 10, and 20 K, respectively. The precision
of the double-integrations could have been compromised slightly by the
superimposed gy component from the b-heme for the 4 K data. The gy and gz components were broadened beyond
detection for T 9 K. Using the same analysis, the
P1/2 values of the S-3 center in the B. subtilis enzyme have been reported as 20 mW (5.5 K) and >300 mW
(7 K), respectively (39, 51). Thus, interestingly, the spin relaxation
of the 3Fe-4S cluster from the P. denitrificans enzyme is
significantly slower than that of the B. subtilis enzyme,
which contains two b-hemes (42).
Fig. 4B depicts the normalized 10 K power saturation data from Fig. 4A and "best fits" of a semiempirical equation describing the power saturation behavior.7 The fits were obtained by "floating" the parameters P1/2 and b (solid curve), or P1/2 only (b = 1.00; dashed curve) in the regression analysis. The parameter estimates for the 10 K data were P1/2 = 1.1 ± 0.2 mW and b = 0.28 ± 0.02 for the solid curve, and P1/2 = 18.1 ± 3.4 mW for the dashed curve; see Table II for estimates of the 4 K data.
The effect of the inhomogeneity parameter, b, is to flatten the curve in the region where part of the spins are being saturated; i.e. in the region where P is comparable to P1/2. For a purely inhomogeneously broadened absorption signal (peak integral), b = 1; the purely homogeneously broadened case yields b = 2. The corresponding values for a derivative-type signal are b = 1 and b = 3, respectively (29). Thus, it is physically impossible for an isolated spin system to be characterized by b < 1, and such a scenario is therefore diagnostic of a dipolar interaction (30). As a result, the analysis provides evidence for enhancement of the spin relaxation of the S-3 center due to magnetic coupling with the b-heme.
Power Saturation Behavior of the S-3 and S-1 Centers in the Succinate- and Dithionite-reduced EnzymesTwo of the three Fe-S clusters are paramagnetic in both the succinate- and dithionite-reduced samples, namely S-1 (ST = 1/2) and S-3 (ST = 2). However, reduction of a sample of SQR with succinate or dithionite yields two distinct levels of reduction. As a result, the redox centers may be diamagnetic or paramagnetic in one or the other state of the enzyme depending on their Em values (see Table I and "Computational Procedures," respectively). Thus, by measuring the power saturation behaviors of the S-1 and S-3 centers in succinate- and dithionite-reduced samples, we expect to observe relief of power saturation of these centers due to fast relaxing centers that are coupled to them.
Fig. 5 depicts the EPR power saturation
behavior of the reduced S-3 (g = 12.6 (A) and S-1
(gx = 1.9 (B), centers in the presence of excess
succinate () and dithionite (and succinate) (
) at 4 K. The
inset in B shows data obtained on the S-1 center at 15 K. The dithionite-reduced samples were noted to be less readily
power-saturated than their succinate-reduced counterparts. Also, the
extent of relief of power saturation is more pronounced for the S-1
center than for the S-3 center (see below). Since reduction of the S-2
center with dithionite causes it to be paramagnetic (see Fig.
2C and Table I), the data demonstrate magnetic couplings between the S-3 and S-2 centers (A), and S-1 and S-2 centers
(B).
In the above we have assumed that the center under observation in the power saturation experiment is the only paramagnetic center in the succinate-reduced enzyme, and that the S-2 center and the center under observation are the only paramagnetic centers in the dithionite-reduced enzyme. However, this is not the case for SQR (see Table I). To ascertain the effects of other paramagnetic centers, we therefore calculated the fractions of protein molecules that contained the center under study, as well as each of the other paramagnetic centers, both for the succinate- and dithionite-reduced states of the enzyme (see below; "Computational Procedures"). Armed with these results, we reconsider our interpretation of the power saturation curves in Fig. 5, A and B.
When changing from the succinate-reduced state to the
dithionite-reduced state of the enzyme, the S-3 center remains reduced, and the b-heme and the S-2 center become reduced (see Table
I). The species consisting of S-3red and oxidized
b-heme (Fe3+), and S-3red and
S-2red, decrease and increase by 98 and 100%, respectively
(subscript red denotes reduced); thus, S-2red
"substitutes" for Fe3+ when changing E from
71 mV to <
400 mV in the experiment in Fig.
5A.
The percentages of enzyme molecules consisting of S-3red and any of S-1red, Q·, or FAD· also change upon reduction of the succinate-reduced sample with dithionite (10, 11, and 33%, respectively). However, these changes are inconsequential to the analysis, as radicals are not capable of relaxing a metal center, and the S-1 center relaxes much slower than the S-3 center at 4 K (see Table II).
When changing from the succinate-reduced state to the dithionite-reduced state of the enzyme the protein species containing S-1red and Fe3+, and S-1red and S-2red decrease by 89% and increase by 100%, respectively. Thus, in the experiment in Fig. 5B these enzyme species are also affected most by reduction of the succinate-reduced sample with dithionite.
Enzyme molecules consisting of S-1red and either FAD·or Q· (30 and 10%, respectively), are (again) affected to a lesser extent, and (again) the radicals are not capable of relaxing the iron-sulfur clusters, the 2Fe-2S cluster in this case. The percentage concentration of the protein species containing S-1red and S-3ox remains essentially unchanged, and therefore, it could not have caused the relief of power saturation observed in the experiment, either at 4 or 15 K (inset). However, the species containing S-1red (ST = 1/2) and S-3red (ST = 2) increases by 10% upon dithionite reduction of the sample. Thus, there is a possibility that there is a minor contribution to the relief of power saturation from relaxation enhancement of S-1red by S-3red through a putative magnetic interaction (52, 53). There is precedent for an interaction between the oxidized S-3 center (ST = 1/2) and the reduced S-1 center in Micrococcus luteus (54) and B. subtilis (55).
Taken together, the minor relief of power saturation of the succinate-reduced S-3 center upon reduction of the sample with dithionite (Fig. 5A) may be due to substituting the b-heme with the S-2 center as the interacting partner. However, it remains possible that the S-2 center is more efficient at relaxing the S-1 center than it is at relaxing the S-3 center. This scenario would also result in minor relief of power saturation.
In the case of the S-1 center (Fig. 5B), there is substantial relief of power saturation due to the S-2 center becoming paramagnetic in the dithionite-reduced state of the enzyme. This observation suggests that the 2Fe-2S cluster is not coupled to the b-heme. This finding is consistent with the topology of this iron-sulfur cluster within the iron-sulfur protein (see Fig. 10 in Ref. 7).
In the present work we have characterized the EPR signals observed in air- and ferricyanide-oxidized, and succinate- and dithionite-reduced SQR purified from P. denitrificans. We have focused in particular on elucidating the magnetic interactions operating between the metal centers and simulating the EPR signals from the radicals.
EPR Fingerprinting StudiesBacterial respiratory chains are generally dominated by features originating from SQR (44, 56). As a general comparison, we obtained spectra of membranes from a P. denitrificans strain (PD1222/pPSD100) overproducing SQR (Figs. 1 and 3F). These spectra were highly similar to those of the purified enzyme (Figs. 2 and 3A; ATCC no. 13543 strain) at the three levels of reduction of the protein. Therefore, we conclude that the purified enzyme has been prepared in its native state.
EPR Spectral Simulations of the Radical SignalsThe two
Q· in the FAD·-2Q· simulations were taken to be
isolated spins; i.e. no dipolar interaction between them
needs to be included. Since a dipolar-coupled signal is observed for
the Q· pair in the bovine heart enzyme (3, 4, 45-47, 57) and that of a variety of higher plants (5), it may be expected that such an
interaction would also operate in the P. denitrificans enzyme. However, we predict a maximal spin concentration of 55% Q·: FAD at E = 5 mV (i.e.
(EmQ/Q· EmQ·QH2)/2) instead of
11%5 as determined from the spin-concentration and EPR
simulations of the ATCC no. 13543 strain. Thus, (redox) poising the
enzyme with a large excess of succinate (E
71 mV)
is most likely not optimal for eliciting substantial spin
concentrations of Q·. This may also be the main reason for the
signal being well simulated by two noninteracting Q. In
addition, the sample with the full complement of Q (Q2) has
less Q·:Q (see Fig. 3, A and C) than the
sample with 0.7 Q (Q10):FAD. This result suggests that the
enzyme has greater affinity (lower Kd) for the
native Q10.
The analysis used in Fig. 4B provides evidence for a magnetic interaction between the cytochrome b and the S-3 center in their respective oxidized states; see Results. In the following, we shall argue that Fig. 4A also presents evidence for the interaction.
The analysis used in Fig. 4A corrects for extended sample
geometry, unlike the one used in Fig. 4B. That is, the
magnetic component of the microwave magnetic field is not constant
inside the EPR cavity, and this is corrected for by sampling
(averaging) the field over the dimensions of the cavity. It is evident
from Fig. 4A that inclusion of such a correction term in the
(analytical) equation (27, 28) accommodates some of the
"flattening" (inhomogeneity) effect for P P1/2 (see also "Results"). However, upon
closer inspection of the 10 K data, it becomes clear that it does so less well than the empirical fit6 with b = 0.3 (solid line in Fig. 4B). Notably, however,
the curve to the 10 K data in Fig. 4A was simulated assuming
a 100% gaussian distribution for the individual spin packet line
shapes; i.e. 100% inhomogeneous broadening. Using <100%
inhomogeneous broadening resulted in a worse fit. In this regard, it is
worth considering that one phenomenon giving rise to inhomogeneous
broadening, is a dipole-dipole interaction between nonidentical centers
(27). Thus, taken together, both analyses provide evidence for the fact that the spin relaxation of the oxidized 3Fe-4S is enhanced by a (weak)
dipolar interaction provided by the fast relaxing spin of the
b-heme (oxidized).
Previous indirect evidence obtained on the bovine heart enzyme also points to the S-3 center being proximal to the b-heme. The sensitivity of the S-3 center in succinate dehydrogenase to molecular oxygen (58) is consistent with our evidence for a magnetic interaction between the b-heme and the 3Fe-4S cluster.
Estimation of the Intercenter Distance between the S-3 Center and the b-Heme in the Air-oxidized EnzymeFrom the absence of
observable (~0.5 mT) splittings in the g = 2.01 signal, a lower
limit of ~1.8 nm between the 3Fe-4S cluster and the b-heme
may be estimated assuming dipolar
coupling8 (7, 52). However,
these splittings may be obscured due to the large anisotropy of the
b-heme signal and the relative orientations of the principal
axes of the two centers with respect to each other and the magnetic
field. A significant exchange-interaction (J) may be
excluded, as it could not have resulted in a "signature" signal for
an oxidized 3Fe-4S cluster, namely gav-value = 2.01 (where gav = (gx + gy + gz)/3)
(59). Therefore, we estimate a distance (r) of 0.5 < r 2 nm.
In samples reduced with excess
succinate and dithionite, we observed for the first time for SQR or QFR
a spectral feature originating from a reduced 3Fe-4S cluster
(ST = 2; see Table I). The resonance is observed at
low-field (g 13), and is consistent with a
MS = 4 transition within the reduced cluster
(43). Observation of (part of) such a "quarter-field" resonance at
X band implies that
0.3 cm
1, where
is the energy splitting between the MS = ± 2 ground
state levels (60, 61). From similar observations on natural and
synthetic cuboidal 3Fe-4S clusters (see Table VI in Ref. 62) and a
suitable spin hamiltonian,9
we may estimate D
2.5 cm
1 and
E/D = 0.20-0.25, respectively, where D and
E denote the axial and rhombic zero field splitting
parameters, respectively.
The relief of power saturation of the S-3 and S-1 centers upon reduction of the succinate-reduced samples with dithionite (Fig. 5) has been taken as evidence for weak dipolar interactions between the centers in question and the S-2 center. Similar decreases in the T1 values of succinate-reduced S-1 centers upon reduction with dithionite have been observed in bovine heart SQR (38), B. subtilis succinate:menaquinone reductase (39), and Escherichia coli fumarate reductase (40). A magnetic interaction between the reduced S-2 and S-3 centers has also been inferred from soluble (succinate dehydrogenase) preparations partially or almost completely devoid of 3Fe-4S cluster (1).
ConclusionsIn this work we have shown that the
fingerprinting spectra obtained on the P. denitrificans
enzyme are largely similar to those of the bovine heart enzyme, with
the exception of the Q· signals. It has been demonstrated by EPR
simulation that P. denitrificans SQR binds two Q·;
however, their Em values are ~100 mV lower than in the bovine heart enzyme. A weak dipolar interaction between the S-3
center and the b-heme in the oxidized enzyme has been
revealed by power saturation experiments. A similar magnetic
interaction may exist in the reduced enzyme, as revealed by
power-saturation data obtained on the succinate- and dithionite-reduced
samples and redox calculations. This is the first evidence obtained on the intact complex for a close proximity of these two centers. Taken
together, these EPR data are entirely consistent with the topological
picture postulated by Ohnishi (see Fig. 10 in Ref. 7). That is, the
three iron-sulfur clusters are located in the iron-sulfur protein
within 2 nm of each other, and the S-3 center is the iron-sulfur
cluster in closest proximity (2 nm) to the b-heme in the
QP.
We thank the late Dr. Vladimir Sled for valuable correspondence. Drs. Siegfried Musser and Brian Schultz are thanked for stimulating discussions and advice with EPR simulations, respectively.