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Ubisemiquinone radicals from the cytochrome b−c1 complex of the mitochondrial electron transport chain—Demonstration of QP-S radical formation
Vol. 99, No. 4,198l April
BIOCHEMICAL
AND EIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages 1411-1419
30, 1981
UBISEMIQUINONE RADICALS FROM THE CYTOCHROME b-c1 COMPLEX OF THE MITOCHONDRIAL ELECTRON TRANSPORT CHAIN--DEMONSTRATION OF QP-S'WICAL FORMATION Yau-huei Wei, Charles P. Scholes and Tsoo E. King Departments of Chemistry and Physics State University of New York at Albany, Albany, New York 12222
Received
March
16,
1981 Summary
Stable ubisemiquinone radical(s) in the cytochrome b-c -II complex of 1n the presence of bovine heart was observed following reduction by succinaTecatalytic amounts of succinate dehydrogenase. The radical was abolished by addition of antimycin A, but a residual radical remained in the presence of excess exogenous Qa. The radical showed an EPR signal of g = 2.0046 + .003 at X band ("9.4 GHz) with no resolved hyperfine structure and had a line width of 8.1 + -5 Gauss at 23°C. The Q band (35 GHz) spectra showed wellresolved g--anisotropy and had a field separation between derivative extrema This radical is evidently from QP-C. These observations of 26 f 1 Gauss. substantiate that the radical is immobilized and bound to a protein. The QP-S radical was demonstrated in the cytochrome complex only in the --b-cl-II presence of more than a catalytic amount of succinate dehydrogenase and cytochrome --b-c . This signal was not antimycin A inhibitory. The signal amplienzymic activity of succinate-cytochrome c tude paral 1 eled the reconstitutive reductase from succinate dehydrogenase and the cytochrome complex. -b-cl-11 -Introduction: made more than none
in
Although twenty
the discovery
years
the mitochondrial
ago
(1,2),
electron
the
of ubiquinone sequence
transport
chain
in mitochondria
and mechanism 1
is
still
not
was
of ubiquiclear
(see
n
e.g.
3,4).
nate-Q
The recent
reductase
reconstitution dehydrogenase
discovery
segment of the
of a Q-binding
of the respiratory
so-called
succinate-Q
(SDH) and QP-S (8,9)
1 Electron transfer terms) used is actually or all other species if transfer.
has cast
protein
chain
(5-7)
reductase certain
(QP-S)‘
in
the succi-
and the successful from
doubt
soluble about
succinate the mobile
(electron transport, electron pathway, or related an abbreviation including the transport of hydrogen those species indeed occur in the respiratory chain
n
'DPPH, a, or-diphenyl-S-picrylhydrozyl; Q, ubiquinone, the subscript indicates the number of isoprenoid units; QP, ubiquinone bound to a specific protein; QP-C, ubiquinone protein that occurs in the cytochrome --b-c l region; protein that exists in the NADH dehydrogenase segment; QP-N, a ubiquinone QP-S, a ubiquinone protein that accepts electrons directly from SDH; QHa fully reduced ubiquinone; SDH, soluble, reconstitutively active succinate dehydrogenase: TTFA, theonyltrifluoroacetone.
Vol. 99, No. 4,198l
nature
as well
obtained
BIOCHEMICAL
as Q-pool
thus
far
AND
theory
has indicated
BIOPHYSICAL
of ubiquinone
(10-12).
the
of at least
existence
binding
proteins
in
the respiratory
chain
quinone
radicals
in
the cytochrome
--b-cl -III3
genase
segment
(QP-N)
have been
in
the order
Trumpower
(15)
radicals
exist
to demonstrate have
nase
only
have in
favor
claimed
(3,13).
form
two different
--b-cl.
of QP-S radicals
(cf -*
that
the
In this
succinate-Q QP-S radical(s)
communication
and other
EPR properties
in bovine
heart
ubisemi-
2
constant Ohnishi
is and
of ubisemiquinone
However,
active
Q-
and NADH dehydro-
3,4).
populations
of reconstitutively
radical(s)
(QP-C)
-c reductase.
found
stable
The dismutation
QP-S in the reconstituted we have
evidence
two additional
In fact,
(3,14).
COMMUNICATIONS
Collective
complex
of a non-radical that
in the presence
on the ubisemiquinone
reported
succinate-cytochrome
isolated
and cytochrome
stration
in
Recently
failed.
strated
of lOlo
RESEARCH
numerous reductase
including cytochrome
system
may be demon-
succinate
we wish
efforts
to report Q-band --b-cl-II
dehydrogethe
demon-
spectra complex.
Materials and Methods: The preparations of SDH and the cytochrome --b-clII complex were made and assayed essentially as previously reported (16) with some modifications. X-band EPR measurements were conducted in a Varian E-4 EPR spectrometer and Bruker ER-420 EPR spectrometer at room and liquid nitrogen temperatures. Q-band EPR studies at 35.0 GHz were done in a Varian nitrogen temperatures. Model V-450214503 spectrometer at room, ice and liquid Fumarate and TTFA were recrystallized from ethanol. Qz was synthesized in this laboratory (14). Since the ubisemiquinone radical was found to be rather sensitive to ethanol, both TTFA and antimycin A were dissolved in dimethylsulfoxide and stored at 0-4°C. A flat EPR cuvette was used for room temperature study in a Varian E-4 EPR spectrometer. About 0.4 mm diameter capillaries The ice temperature was obtained were employed for the Q-band EPR studies, by putting the Q-band cavity into a small Dewar containing an ice-water mixture. A small flat cell that fits into the Bruker B-VT 1000 variable temperature flow Dewar was used for controlled temperature X-band work. At X-band a Hewlett Packard Model 52408 12.4 GHz Frequency Counter and a Harvey-Wells Model G502 NMR probe were used for measuring the EPR frequency and magnetic field strengths needed to compute g-values. At Q band a very small piece of DPPH (with known g-value of 2.0036) was placed in the EPR cavity for some experiments, and g-values of the ubiquinone radical were measured with respect to it. The magnetic field sweep range used at Q band had been calibrated by 3 The cytochrome complex is prepared from succinate-cytochrome c --b-cl-1 reductase and is insoluble. The cytochrome complex is identical --b-cl-II functionally with the b-cl-I complex except its aqueous solubility. Both can -reconstitute with soluble SDH to form succinate-cytochrome c reductase. Removal of QP-S from the -b-cl-II complex yields the cytochrome com--b-cl-III plex and thus the complex is reconstitutively inactive with SDH. However, succinate-cytochrome 2 reductase is physically and functionally formed by admixture of the --b-cl-111 complex, QP-S and SDH (8).
1412
3
BIOCHEMICAL
Vol. 99, No. 4,198l
OO L/,
AND
BIOPHYSICAL
4/
6
12 1
1
RESEARCH
J
COMMUNICATIONS
16 II
TIME (mini
Fig.
Correlation of the reductions of cytochrome band 21 with the formation of protein-bound ubisemiquinone radical in cytochrome b-cl-II complex. The system used for a and ~1 reduction contained i.2 mg b-cl-11 complex (9.1 nmolb and 4.8 nmol 21) 7.5 x low3 nmol SDH and i.7 nmol Qz in 0.72 ml total volume. The reductions of b and c were followed right after addition of 1.0 ~1 of a substrate mix-t ure, containing 60 mM fumarate and 15 mM succinate, by following the difference spectra in a Amico DW-2 spectrophotometer using an identical sample without substrate as reference. The system used for Q radical signal measurement in a Varian E-4 EPR spectrometer contained 10.8 mg b-cl-II complex (82 nmolb and 43 nmolcl), 6.7 x lo-* nmol SDH and i7-nmol Q2 in 0.18 ml total volume. The Q radical production was initiated by addition of a 10 nl substrate mixture containing 60 mM fumarate and 15 mE1succinate to the system and the signal was monitored at the peak of absorption with the machine settings of microwave frequency 9.492 GHz, microwave power 100 mW, 100 KHz field modulation of 5.0 Gauss amplitude, time constant 1.0 set, scan rate 50 Gauss/min. The EPR and optical recordings are all carried out at 23°C.
1.
reference to the 32 Gauss splitting of the outer features from a mobile nitroxide spin label. Signal to noise of the Q band work and X-band Bruker work was enhanced by repetitive spectral accumulation in a Tracer 570 Signal Averager. Results study
and Discussions:
contained
not
less
2.0 nmol ubiquinone in electron be initiated amounts dependent Before
tion
This
radical
b (cf.
this
segment
reduced
to the degree
Fig.
cytochrome
was stable
appeared
--b-cl -11
radical(s)
oxygen,
of reduction of cytochrome
plus
The ubisemiquinone
chain
radical
could
catalytic
of cytochromes
concomitantly
b,
involved
and showed
~1 almost
in this
cytochrome
of the respiratory
towards
1413
used
6.3 nmol
Qs or succinate
approximately 1).
~1,
complex
The ubisemiquinone
of the reduction
and the signal
of cytochrome
in
of either
related
the completion
observed,
3.5 nmol
reactions
by addition
change,
than
per mg protein.
transfer
of SDH.
The cytochrome
a timec -b and -1'
no signal with
was
the reduc-
was found
to
BIOCHEMICAL
Vol. 99, No. 4,1981
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
THE k-c,-IICOYPLEX 50
Fig.
2.
be greatly
The effect of the fumarate to succinate ratio on the stability of the protein-bound ubisemiquinone radical. The systems all contained 12.6 mg b-c -11 complex (75 nmol b and 44 nmol c ), 0.12 nmol SDH and 185 Km: 1 Qs in a total volume-of 0.22 ml. Ekfferent ratios of fumarate-succinate mixture were added to the reconstituted enzyme solution and the RPR signals of the Q radical formed thereof were monitored under identical Varian E-4 machine settings of microwave frequency 9.492 GRz, microwave power 100 mW, 100 KHz field modulation of 8.2 Gauss amplitude, time constant 3.0 see, scan rate 25 Gauss/min. The signals were followed until equilibrium was reached. The total concentration of fumarate plus succinate was maintained at about 25 mM in each system.
stabilized
and intensity Fig.
2.
ratio the
were
dependent
The maximal
approached radical
4.
fumarate
to succinate
rapidly,
reached
various
In the
range
slowly
fumarate
were
and then
by titration to succinate This
for
oxidized
QP-C reduced/QP-C couple)
using
The ubisemiquinone of catalytic g=
2.0046
amount + .0003
is
at s9.4
GHz with
several
of 5 to 20, hours
When mixtures
the ubisemiquinone
radical
to a constant amplitude
protein -b-cl-III --
in cytochrome
SDH showed
for
an EPR signal no resolved
1414
bound
even at of lower
formed
level
(cf.,
of ubisemiquinone
with
hyperfine
of Em
bound
(17).
complex
of typical
against
value
ubiquinol/protein
--b-cl-II
Fig.
+50 mV at 23" and
the overall
complex
in
to succinate
was reached.
in agreement
the cytochrome
as shown
ratios
a Em of approximately
(i.e.
radical of
constant
of signal
value
ratio,
to succinate
decreased
ratios,
pH 7.4 was obtained.
ubiquinone
used,
appearance
when the fumarate
of fumarate
height
signal
to succinate
and remained
ratios
and its
fumarate,
was reached
the maximal
a maximum,
At equilibrium,
2) *
height
after
of
on the fumarate
signal
was formed
room temperature
the presence
in
free
in the presence radical
structure.
at The line
BIOCHEMICAL
Vol. 99, No. 4,198l
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
MAGNETIC FIELD (GAUSS1
Fig.
The EPR spectrum of the protein-bound ubisemiquinone radical in the cytochrome b-c,-11 complex observed in Q-band RPR spectrometer. The system contai;ed about 0.01 ml sample in a thin capillary EPR tube (0.04 x 8 cm). The sample contained 0.48 mg b-c -II complex (9.7 nmol -1c with b_- to --1 c ratio of about 1.8), 2 x-15" nmol SDH, 8 nmol Q2 and 120 nmol fumarate and 45 nmol succinate as substrate in a total volume of 0.01 ml. The spectrum was taken at ice (%O"C) temperature on a Varian Model V-4502/4503 Q-band EPR spectrometer using the settings of microwave frequency 34.99 GHz, microwave power
3.
10 dB (%lO mW), 100 Kllz field modulation of 4 Gauss amplitude, constant of 0.1 set, and scan rate 100 Gauss/min, with a total 3 accumulations in the signal averager.
width
of this
signal,
estimated
at room temperature
and
the ubisemiquinone,
i.e.
8.4
f
anisotropic
It
a field
showed
illustrated ble
strongly
reaction
those
centers
the QP-C radical none radical 4
The ice disappearance
at
EPR spectrum
3 taken
at ice
reported
at
strongly not
1.3"K
(sO"C)
--et al.
(18).
a freely
and would
temperature and room temperature of the radical signal was slower
amounts
+
0.5
when
of a and 77°K.
of 26 ? 1 Gauss, These
in bacterial
since
conditions,
at room temperature
temperature.4
by Feher
these
8.1
EPR spectrometer,
extrema
radical
was
suitable
in a Q-band
derivative
immobilized
showg-anisotropy,
with
was observed
between
extrema,
Under
77°K.
formed
of ubisemiquinone
is
would
Gauss
was examined
separation
in Fig.
0.5
the derivative
QP-C radical,
fumarate-succinate-mixture, prominent
between
time of
spectra
as resem-
photosynthetic This tumbling
show resolved
indicates
that
ubisemiquihyperfine
EPR spectra were identical at ice temperature.
but
Vol. 99, No. 4,198l
structure, These
BIOCHEMICAL
and substantial
observations
immobilized
line
clearly
and bound
of excess
remained
(21);
On the other reason
quinone this
hand, for
could
signal
above was found
~1 in
the
inhibition
of this
radical
is not
amount
clear
completely
of SDH, was the in the
cytochrome
although
sufficient
amount
of QP-S was present
simple
ubisemiquinone When the amount sensitive
as well
as at 77".
added
the enzymic lation
complex
activity
indicated.
It
with
less
amplitude
most
likely
Q (22,23).
It
is
concluded in
appeared under
the
complete;
this
complex
systems,
ubisemi-
the presence no QP-S
conditions
system
to generate
another
EPR signal
was found
to be approximately
signal
11 Gauss at
was proportional The signal
systems.
to the
amplitude
Figure
4 shows the
of SDH to the cytochrome
might
be noted
that
the
SDH was used;
this
semiquinone comparable
radical
width
of SDH which
center
1416
corre-
with
of this
was evidently
to the ubisemiquinone. interaction
e.g.
line
activity
SDH
paralleled
EPR signal
at ratios
which
at room temperature
2 reductase
species,
that
that
the
at g = 2.00
the systems.
due to the spin-spin
paramagnetic
with
succinate-cytochrome
the flavin intensity
in
A appeared
of this
in
when more and more
overlapping
radical
Since
A, it
complex
the
of the reconstituted
A-insensitive
increased
another
complex
of reconstituted
antimycin
width
The amplitude
to the --b-cl-II
in
antimycin
The line
room temperature.
in the
of QP-S.
of SDH increased
towards
antibiotic
However,
competes
b-cl-11 --
--b-cl -11
to
ubisemiquinone
QP-C radical.
was involved
radical
system.
at present.
cytochrome
sensitive
by TTFA was never
by antimycin
from
is
of this
Q 2, some residual antimycin
was formed
to be very
the
(19).
(20).
by addition
because
which
was not
radical
apparently
incompleteness
of a catalytic
ubisemiquinone earlier
abolished
COMMUNICATIONS
of temperature
as proposed
added
RESEARCH
upon change
is
be abolished
radical,
this
to cytochrome
exogenously
this
changes
that
be completely
concentration
presence
the
indicate
described
A and could
at equimolar
shape
to a protein
The ubisemiquinone antimycin
AND BIOPHYSICAL
the b-c -- l-II
signal
was
due to spectral possesses The signal
of ubisemiquinone S-3 of SDH as suggested
much is
of QP-S with by Beinert
BIOCHEMICAL
Vol. 99, No. 4,198l
AND
BIOPHYSICAL
WHIP-&-II
Fig.
4.
(personal --b-cl
communication).
abolished
flux
that
to the steady
involving
this
signal
substantiated
QP-S is is
-b-cl-_ -11
SDH was present
of Qe.
state being
kinetics further
radical
investigated.
plus
amounts
a catalytic (e.g.
of the ubisemiquinone The half-time
that
generated
1417
antimycin
by addition amount
reduction These
This
facts
conclusion
A completely of exogenous
of SDH, but
not
QZHZ so when
>20%). radicals
to reach
of the cytochrome
of cytochrome
due to the QP-S ubisemiquinone.
complex
in greater
The formation
of the presence
by the observation
the ubisemiquinone
to cytochrome
by addition
mole ratio
The requirement
related
and electron
was further
COMMUNICATIONS
Correlation of reconstituted succinate-cytochrome c activity and the antimycin A-insensitive EPR signal amplitude. Reconstituted reductase preparation was made from different amounts of SDH to the b-cl-11 complex as shown by the mole ratios on abscissa. The enzymic activity (*) of each system was assayed spectrophotometrically by following the reduction of cytochrome 2 at 550 nm. The reconstituted reductase preparation for EPR studies were identical with those used for activity assay and contained 20 to 70 mg per ml solution. For RPR studies, each system was preincubated with 4 ~1 of 10 mM antimycin A for 10 minutes at 4°C. The EPR signals were initiated by addition of 15 ~1 substrate solution containing 60 mM fumarate and 10 mM succinate, and the spectra were recorded after the signals reached equilibrium at 23°C. The signal amplitude (A) was normalized on the basis of cytochrome --1 c concentration in each system.
apparently
indicate
RESEARCH
was found
the maximal
signal
to be stimulated height
was
Vol. 99, No. 4,198l
decreased
when
BIOCHEMICAL
the concentration
of the ubisemiquinone
complex
of this
only
Q2 titration This
a fraction that
deficiency
transfer
activity
required
more exogenous
An optimum complex
level
was found
again
of that
of ubiquinone and both
of the
in this
antimycin
Q than
which
A sensitive
for
the antimycin
summation
of exogenous
to be two mol of Q per
supports
the existence
Acknowledgement--Experimental from NIH and the American Cancer
cl,
40% --b-cl-
the results
was deficient
in
of the preparation
is known
segment
about
of the cytochrome
complex
a result
intensity
to increase
of cytochrome
the b-cl-11 --
fractionation
COMMUNICATIONS
The EPR signal
content
was apparently
ammonium sulfate-cholate The amount
RESEARCH
was found
the ubiquinone
indicates
Q (1’3).
tion
at equilibrium
Since
was usually
ubiquinone. ing
Q2.
EIOPHYSICAL
of Q2 increased.
radical
by externally-added II
AND
for
to be able
showing
to remove
maximal
and insensitive
electron
EPR signals
A-sensitive
signal
and endogenous
mol of cytochrome
involv-
alone.
Q in the --b-cl The observa-
cl.
of QP-S and QP-C.
work was generously Society.
supported
by grants
References 1.
Green, D. E. (1961) in 'Quinones Wolstenholme and C.M. O'Connor,
2.
Morton, London.
3.
King, T. E. (1980) in to Professor K. Yagi" eds.), Japan Scientific
4.
King, Vol.
5.
Yu, C. A., Yu, L. and King, 78, 259-265.
6.
King, T. E., Yu, L., Nagaoka, S., Widger, W. R., and Yu, C. A. (1978) in "Frontiers of Biological Energetics" Vol. 1 (L. Duttin, J. Leigh, and T. Scarpa, eds.) Academic Press, New York, pp. 174-182.
7.
Yu,
8.
Yu, C. A., Yu, L. and King, 79, 939-946.
T.E.
9.
Yu, C. A. and
Biochim.
R. A.
(ed.)
T. E. (1981) 3 (K. Folkers,
(1965)
Biochemistry
of Quinones,
(G.E.W.
Academic
Press,
"New Horizons in Biological Chemistry--Fetschaft (M. Koike, T. Nagatsu, J. Okuda and T. Ozawa, Sot. Press, Tokyo, pp. 121-134.
in "Biomedical and Clinical Aspects of Coenzyme Q," ed.), Elsevier-North Holland, Amsterdam (in press).
C. A. and Yu, L.
Yu,
in Electron Transport" eds.) Churchill, London.
L.
(1980)
(1980)
T. E. (1977)
Biochemistry
Biochem.
19,
(1977)
14 18
Res.
Commun.
3579-3585.
Biochem.
Biophys.
Biophys.
Biophys.
Acta 591,
Res. 409-420.
Commun.
BIOCHEMICAL
Vol. 99, No. 4,1981
D. E. (1961)
AND
BIOPHYSICAL
Green,
11.
Kroger,
A. and Klingenberg,
21. (1973)
Eur.
J. Biochem.
3,
358-368.
12.
Kroger,
A. and Klingenberg,
M. (1973)
Eur.
J. Biochem.
2,
313-323.
13.
Yu, C. A., Nagaoka, S., Yu, L. and King, Res. Commun. g, 1070-1078.
14.
Yu, C. A., Nagaoka, Biophys. 2, 59-70.
15.
Ohnishi,
16.
Yu,
17.
Nagaoka, press).
18.
Feher, G., Okamura, Acta 267, 222-226.
19.
Das, M. R., Connor, H. D., Keniart, J. Am. Chem. Sot. 92, 2258-2268.
20.
King, T. E. (1978) in "Membrane Proteins" P. L. Jdrgensen, and A. J. Moody, eds.), 17-31.
21.
King, ed.),
22.
Takemori,
S. and King,
T. E. (1964)
Science
23.
Takemori,
S. and King,
T. E. (1964)
J. Biol.
C. A.,
S.,
Yu, L.,
and Trumpower, Yu, L. and King,
S.,
& Physiol.
81-122.
T. E. (1978)
and King,
B. L.
4,
COMMUNICATIONS
10.
T.,
Comp. Biochem.
RESEARCH
Biochem.
T. E. (1980)
Arch.
Biophys. Biochem.
(1980)
J. Biol.
Chem. 255,
3278-3284.
T. E. (1974)
J. Biol.
Chem. 249,
4905-4910.
Yu, L. and King,
T. E. (1981)
M. Y. and McElroy,
T. E. (1981) in "Quinones Academic Press, New York
Arch.
J. D.
Biochem.
(1972)
D. S. and Freed,
1419
Biochim.
Coupling" l&,
Biophys.
J. H. (1970)
(P. Nicholls, Pergamon Press,
in Energy (in press).
Biophys.
J. V. Mbller, Oxford, pp.
(B. L. Trumpower, 852-853.
Chem. 239,
3546-3558.
(in
BIOCHEMICAL
AND EIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages 1411-1419
30, 1981
UBISEMIQUINONE RADICALS FROM THE CYTOCHROME b-c1 COMPLEX OF THE MITOCHONDRIAL ELECTRON TRANSPORT CHAIN--DEMONSTRATION OF QP-S'WICAL FORMATION Yau-huei Wei, Charles P. Scholes and Tsoo E. King Departments of Chemistry and Physics State University of New York at Albany, Albany, New York 12222
Received
March
16,
1981 Summary
Stable ubisemiquinone radical(s) in the cytochrome b-c -II complex of 1n the presence of bovine heart was observed following reduction by succinaTecatalytic amounts of succinate dehydrogenase. The radical was abolished by addition of antimycin A, but a residual radical remained in the presence of excess exogenous Qa. The radical showed an EPR signal of g = 2.0046 + .003 at X band ("9.4 GHz) with no resolved hyperfine structure and had a line width of 8.1 + -5 Gauss at 23°C. The Q band (35 GHz) spectra showed wellresolved g--anisotropy and had a field separation between derivative extrema This radical is evidently from QP-C. These observations of 26 f 1 Gauss. substantiate that the radical is immobilized and bound to a protein. The QP-S radical was demonstrated in the cytochrome complex only in the --b-cl-II presence of more than a catalytic amount of succinate dehydrogenase and cytochrome --b-c . This signal was not antimycin A inhibitory. The signal amplienzymic activity of succinate-cytochrome c tude paral 1 eled the reconstitutive reductase from succinate dehydrogenase and the cytochrome complex. -b-cl-11 -Introduction: made more than none
in
Although twenty
the discovery
years
the mitochondrial
ago
(1,2),
electron
the
of ubiquinone sequence
transport
chain
in mitochondria
and mechanism 1
is
still
not
was
of ubiquiclear
(see
n
e.g.
3,4).
nate-Q
The recent
reductase
reconstitution dehydrogenase
discovery
segment of the
of a Q-binding
of the respiratory
so-called
succinate-Q
(SDH) and QP-S (8,9)
1 Electron transfer terms) used is actually or all other species if transfer.
has cast
protein
chain
(5-7)
reductase certain
(QP-S)‘
in
the succi-
and the successful from
doubt
soluble about
succinate the mobile
(electron transport, electron pathway, or related an abbreviation including the transport of hydrogen those species indeed occur in the respiratory chain
n
'DPPH, a, or-diphenyl-S-picrylhydrozyl; Q, ubiquinone, the subscript indicates the number of isoprenoid units; QP, ubiquinone bound to a specific protein; QP-C, ubiquinone protein that occurs in the cytochrome --b-c l region; protein that exists in the NADH dehydrogenase segment; QP-N, a ubiquinone QP-S, a ubiquinone protein that accepts electrons directly from SDH; QHa fully reduced ubiquinone; SDH, soluble, reconstitutively active succinate dehydrogenase: TTFA, theonyltrifluoroacetone.
Vol. 99, No. 4,198l
nature
as well
obtained
BIOCHEMICAL
as Q-pool
thus
far
AND
theory
has indicated
BIOPHYSICAL
of ubiquinone
(10-12).
the
of at least
existence
binding
proteins
in
the respiratory
chain
quinone
radicals
in
the cytochrome
--b-cl -III3
genase
segment
(QP-N)
have been
in
the order
Trumpower
(15)
radicals
exist
to demonstrate have
nase
only
have in
favor
claimed
(3,13).
form
two different
--b-cl.
of QP-S radicals
(cf -*
that
the
In this
succinate-Q QP-S radical(s)
communication
and other
EPR properties
in bovine
heart
ubisemi-
2
constant Ohnishi
is and
of ubisemiquinone
However,
active
Q-
and NADH dehydro-
3,4).
populations
of reconstitutively
radical(s)
(QP-C)
-c reductase.
found
stable
The dismutation
QP-S in the reconstituted we have
evidence
two additional
In fact,
(3,14).
COMMUNICATIONS
Collective
complex
of a non-radical that
in the presence
on the ubisemiquinone
reported
succinate-cytochrome
isolated
and cytochrome
stration
in
Recently
failed.
strated
of lOlo
RESEARCH
numerous reductase
including cytochrome
system
may be demon-
succinate
we wish
efforts
to report Q-band --b-cl-II
dehydrogethe
demon-
spectra complex.
Materials and Methods: The preparations of SDH and the cytochrome --b-clII complex were made and assayed essentially as previously reported (16) with some modifications. X-band EPR measurements were conducted in a Varian E-4 EPR spectrometer and Bruker ER-420 EPR spectrometer at room and liquid nitrogen temperatures. Q-band EPR studies at 35.0 GHz were done in a Varian nitrogen temperatures. Model V-450214503 spectrometer at room, ice and liquid Fumarate and TTFA were recrystallized from ethanol. Qz was synthesized in this laboratory (14). Since the ubisemiquinone radical was found to be rather sensitive to ethanol, both TTFA and antimycin A were dissolved in dimethylsulfoxide and stored at 0-4°C. A flat EPR cuvette was used for room temperature study in a Varian E-4 EPR spectrometer. About 0.4 mm diameter capillaries The ice temperature was obtained were employed for the Q-band EPR studies, by putting the Q-band cavity into a small Dewar containing an ice-water mixture. A small flat cell that fits into the Bruker B-VT 1000 variable temperature flow Dewar was used for controlled temperature X-band work. At X-band a Hewlett Packard Model 52408 12.4 GHz Frequency Counter and a Harvey-Wells Model G502 NMR probe were used for measuring the EPR frequency and magnetic field strengths needed to compute g-values. At Q band a very small piece of DPPH (with known g-value of 2.0036) was placed in the EPR cavity for some experiments, and g-values of the ubiquinone radical were measured with respect to it. The magnetic field sweep range used at Q band had been calibrated by 3 The cytochrome complex is prepared from succinate-cytochrome c --b-cl-1 reductase and is insoluble. The cytochrome complex is identical --b-cl-II functionally with the b-cl-I complex except its aqueous solubility. Both can -reconstitute with soluble SDH to form succinate-cytochrome c reductase. Removal of QP-S from the -b-cl-II complex yields the cytochrome com--b-cl-III plex and thus the complex is reconstitutively inactive with SDH. However, succinate-cytochrome 2 reductase is physically and functionally formed by admixture of the --b-cl-111 complex, QP-S and SDH (8).
1412
3
BIOCHEMICAL
Vol. 99, No. 4,198l
OO L/,
AND
BIOPHYSICAL
4/
6
12 1
1
RESEARCH
J
COMMUNICATIONS
16 II
TIME (mini
Fig.
Correlation of the reductions of cytochrome band 21 with the formation of protein-bound ubisemiquinone radical in cytochrome b-cl-II complex. The system used for a and ~1 reduction contained i.2 mg b-cl-11 complex (9.1 nmolb and 4.8 nmol 21) 7.5 x low3 nmol SDH and i.7 nmol Qz in 0.72 ml total volume. The reductions of b and c were followed right after addition of 1.0 ~1 of a substrate mix-t ure, containing 60 mM fumarate and 15 mM succinate, by following the difference spectra in a Amico DW-2 spectrophotometer using an identical sample without substrate as reference. The system used for Q radical signal measurement in a Varian E-4 EPR spectrometer contained 10.8 mg b-cl-II complex (82 nmolb and 43 nmolcl), 6.7 x lo-* nmol SDH and i7-nmol Q2 in 0.18 ml total volume. The Q radical production was initiated by addition of a 10 nl substrate mixture containing 60 mM fumarate and 15 mE1succinate to the system and the signal was monitored at the peak of absorption with the machine settings of microwave frequency 9.492 GHz, microwave power 100 mW, 100 KHz field modulation of 5.0 Gauss amplitude, time constant 1.0 set, scan rate 50 Gauss/min. The EPR and optical recordings are all carried out at 23°C.
1.
reference to the 32 Gauss splitting of the outer features from a mobile nitroxide spin label. Signal to noise of the Q band work and X-band Bruker work was enhanced by repetitive spectral accumulation in a Tracer 570 Signal Averager. Results study
and Discussions:
contained
not
less
2.0 nmol ubiquinone in electron be initiated amounts dependent Before
tion
This
radical
b (cf.
this
segment
reduced
to the degree
Fig.
cytochrome
was stable
appeared
--b-cl -11
radical(s)
oxygen,
of reduction of cytochrome
plus
The ubisemiquinone
chain
radical
could
catalytic
of cytochromes
concomitantly
b,
involved
and showed
~1 almost
in this
cytochrome
of the respiratory
towards
1413
used
6.3 nmol
Qs or succinate
approximately 1).
~1,
complex
The ubisemiquinone
of the reduction
and the signal
of cytochrome
in
of either
related
the completion
observed,
3.5 nmol
reactions
by addition
change,
than
per mg protein.
transfer
of SDH.
The cytochrome
a timec -b and -1'
no signal with
was
the reduc-
was found
to
BIOCHEMICAL
Vol. 99, No. 4,1981
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
THE k-c,-IICOYPLEX 50
Fig.
2.
be greatly
The effect of the fumarate to succinate ratio on the stability of the protein-bound ubisemiquinone radical. The systems all contained 12.6 mg b-c -11 complex (75 nmol b and 44 nmol c ), 0.12 nmol SDH and 185 Km: 1 Qs in a total volume-of 0.22 ml. Ekfferent ratios of fumarate-succinate mixture were added to the reconstituted enzyme solution and the RPR signals of the Q radical formed thereof were monitored under identical Varian E-4 machine settings of microwave frequency 9.492 GRz, microwave power 100 mW, 100 KHz field modulation of 8.2 Gauss amplitude, time constant 3.0 see, scan rate 25 Gauss/min. The signals were followed until equilibrium was reached. The total concentration of fumarate plus succinate was maintained at about 25 mM in each system.
stabilized
and intensity Fig.
2.
ratio the
were
dependent
The maximal
approached radical
4.
fumarate
to succinate
rapidly,
reached
various
In the
range
slowly
fumarate
were
and then
by titration to succinate This
for
oxidized
QP-C reduced/QP-C couple)
using
The ubisemiquinone of catalytic g=
2.0046
amount + .0003
is
at s9.4
GHz with
several
of 5 to 20, hours
When mixtures
the ubisemiquinone
radical
to a constant amplitude
protein -b-cl-III --
in cytochrome
SDH showed
for
an EPR signal no resolved
1414
bound
even at of lower
formed
level
(cf.,
of ubisemiquinone
with
hyperfine
of Em
bound
(17).
complex
of typical
against
value
ubiquinol/protein
--b-cl-II
Fig.
+50 mV at 23" and
the overall
complex
in
to succinate
was reached.
in agreement
the cytochrome
as shown
ratios
a Em of approximately
(i.e.
radical of
constant
of signal
value
ratio,
to succinate
decreased
ratios,
pH 7.4 was obtained.
ubiquinone
used,
appearance
when the fumarate
of fumarate
height
signal
to succinate
and remained
ratios
and its
fumarate,
was reached
the maximal
a maximum,
At equilibrium,
2) *
height
after
of
on the fumarate
signal
was formed
room temperature
the presence
in
free
in the presence radical
structure.
at The line
BIOCHEMICAL
Vol. 99, No. 4,198l
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
MAGNETIC FIELD (GAUSS1
Fig.
The EPR spectrum of the protein-bound ubisemiquinone radical in the cytochrome b-c,-11 complex observed in Q-band RPR spectrometer. The system contai;ed about 0.01 ml sample in a thin capillary EPR tube (0.04 x 8 cm). The sample contained 0.48 mg b-c -II complex (9.7 nmol -1c with b_- to --1 c ratio of about 1.8), 2 x-15" nmol SDH, 8 nmol Q2 and 120 nmol fumarate and 45 nmol succinate as substrate in a total volume of 0.01 ml. The spectrum was taken at ice (%O"C) temperature on a Varian Model V-4502/4503 Q-band EPR spectrometer using the settings of microwave frequency 34.99 GHz, microwave power
3.
10 dB (%lO mW), 100 Kllz field modulation of 4 Gauss amplitude, constant of 0.1 set, and scan rate 100 Gauss/min, with a total 3 accumulations in the signal averager.
width
of this
signal,
estimated
at room temperature
and
the ubisemiquinone,
i.e.
8.4
f
anisotropic
It
a field
showed
illustrated ble
strongly
reaction
those
centers
the QP-C radical none radical 4
The ice disappearance
at
EPR spectrum
3 taken
at ice
reported
at
strongly not
1.3"K
(sO"C)
--et al.
(18).
a freely
and would
temperature and room temperature of the radical signal was slower
amounts
+
0.5
when
of a and 77°K.
of 26 ? 1 Gauss, These
in bacterial
since
conditions,
at room temperature
temperature.4
by Feher
these
8.1
EPR spectrometer,
extrema
radical
was
suitable
in a Q-band
derivative
immobilized
showg-anisotropy,
with
was observed
between
extrema,
Under
77°K.
formed
of ubisemiquinone
is
would
Gauss
was examined
separation
in Fig.
0.5
the derivative
QP-C radical,
fumarate-succinate-mixture, prominent
between
time of
spectra
as resem-
photosynthetic This tumbling
show resolved
indicates
that
ubisemiquihyperfine
EPR spectra were identical at ice temperature.
but
Vol. 99, No. 4,198l
structure, These
BIOCHEMICAL
and substantial
observations
immobilized
line
clearly
and bound
of excess
remained
(21);
On the other reason
quinone this
hand, for
could
signal
above was found
~1 in
the
inhibition
of this
radical
is not
amount
clear
completely
of SDH, was the in the
cytochrome
although
sufficient
amount
of QP-S was present
simple
ubisemiquinone When the amount sensitive
as well
as at 77".
added
the enzymic lation
complex
activity
indicated.
It
with
less
amplitude
most
likely
Q (22,23).
It
is
concluded in
appeared under
the
complete;
this
complex
systems,
ubisemi-
the presence no QP-S
conditions
system
to generate
another
EPR signal
was found
to be approximately
signal
11 Gauss at
was proportional The signal
systems.
to the
amplitude
Figure
4 shows the
of SDH to the cytochrome
might
be noted
that
the
SDH was used;
this
semiquinone comparable
radical
width
of SDH which
center
1416
corre-
with
of this
was evidently
to the ubisemiquinone. interaction
e.g.
line
activity
SDH
paralleled
EPR signal
at ratios
which
at room temperature
2 reductase
species,
that
that
the
at g = 2.00
the systems.
due to the spin-spin
paramagnetic
with
succinate-cytochrome
the flavin intensity
in
A appeared
of this
in
when more and more
overlapping
radical
Since
A, it
complex
the
of the reconstituted
A-insensitive
increased
another
complex
of reconstituted
antimycin
width
The amplitude
to the --b-cl-II
in
antimycin
The line
room temperature.
in the
of QP-S.
of SDH increased
towards
antibiotic
However,
competes
b-cl-11 --
--b-cl -11
to
ubisemiquinone
QP-C radical.
was involved
radical
system.
at present.
cytochrome
sensitive
by TTFA was never
by antimycin
from
is
of this
Q 2, some residual antimycin
was formed
to be very
the
(19).
(20).
by addition
because
which
was not
radical
apparently
incompleteness
of a catalytic
ubisemiquinone earlier
abolished
COMMUNICATIONS
of temperature
as proposed
added
RESEARCH
upon change
is
be abolished
radical,
this
to cytochrome
exogenously
this
changes
that
be completely
concentration
presence
the
indicate
described
A and could
at equimolar
shape
to a protein
The ubisemiquinone antimycin
AND BIOPHYSICAL
the b-c -- l-II
signal
was
due to spectral possesses The signal
of ubisemiquinone S-3 of SDH as suggested
much is
of QP-S with by Beinert
BIOCHEMICAL
Vol. 99, No. 4,198l
AND
BIOPHYSICAL
WHIP-&-II
Fig.
4.
(personal --b-cl
communication).
abolished
flux
that
to the steady
involving
this
signal
substantiated
QP-S is is
-b-cl-_ -11
SDH was present
of Qe.
state being
kinetics further
radical
investigated.
plus
amounts
a catalytic (e.g.
of the ubisemiquinone The half-time
that
generated
1417
antimycin
by addition amount
reduction These
This
facts
conclusion
A completely of exogenous
of SDH, but
not
QZHZ so when
>20%). radicals
to reach
of the cytochrome
of cytochrome
due to the QP-S ubisemiquinone.
complex
in greater
The formation
of the presence
by the observation
the ubisemiquinone
to cytochrome
by addition
mole ratio
The requirement
related
and electron
was further
COMMUNICATIONS
Correlation of reconstituted succinate-cytochrome c activity and the antimycin A-insensitive EPR signal amplitude. Reconstituted reductase preparation was made from different amounts of SDH to the b-cl-11 complex as shown by the mole ratios on abscissa. The enzymic activity (*) of each system was assayed spectrophotometrically by following the reduction of cytochrome 2 at 550 nm. The reconstituted reductase preparation for EPR studies were identical with those used for activity assay and contained 20 to 70 mg per ml solution. For RPR studies, each system was preincubated with 4 ~1 of 10 mM antimycin A for 10 minutes at 4°C. The EPR signals were initiated by addition of 15 ~1 substrate solution containing 60 mM fumarate and 10 mM succinate, and the spectra were recorded after the signals reached equilibrium at 23°C. The signal amplitude (A) was normalized on the basis of cytochrome --1 c concentration in each system.
apparently
indicate
RESEARCH
was found
the maximal
signal
to be stimulated height
was
Vol. 99, No. 4,198l
decreased
when
BIOCHEMICAL
the concentration
of the ubisemiquinone
complex
of this
only
Q2 titration This
a fraction that
deficiency
transfer
activity
required
more exogenous
An optimum complex
level
was found
again
of that
of ubiquinone and both
of the
in this
antimycin
Q than
which
A sensitive
for
the antimycin
summation
of exogenous
to be two mol of Q per
supports
the existence
Acknowledgement--Experimental from NIH and the American Cancer
cl,
40% --b-cl-
the results
was deficient
in
of the preparation
is known
segment
about
of the cytochrome
complex
a result
intensity
to increase
of cytochrome
the b-cl-11 --
fractionation
COMMUNICATIONS
The EPR signal
content
was apparently
ammonium sulfate-cholate The amount
RESEARCH
was found
the ubiquinone
indicates
Q (1’3).
tion
at equilibrium
Since
was usually
ubiquinone. ing
Q2.
EIOPHYSICAL
of Q2 increased.
radical
by externally-added II
AND
for
to be able
showing
to remove
maximal
and insensitive
electron
EPR signals
A-sensitive
signal
and endogenous
mol of cytochrome
involv-
alone.
Q in the --b-cl The observa-
cl.
of QP-S and QP-C.
work was generously Society.
supported
by grants
References 1.
Green, D. E. (1961) in 'Quinones Wolstenholme and C.M. O'Connor,
2.
Morton, London.
3.
King, T. E. (1980) in to Professor K. Yagi" eds.), Japan Scientific
4.
King, Vol.
5.
Yu, C. A., Yu, L. and King, 78, 259-265.
6.
King, T. E., Yu, L., Nagaoka, S., Widger, W. R., and Yu, C. A. (1978) in "Frontiers of Biological Energetics" Vol. 1 (L. Duttin, J. Leigh, and T. Scarpa, eds.) Academic Press, New York, pp. 174-182.
7.
Yu,
8.
Yu, C. A., Yu, L. and King, 79, 939-946.
T.E.
9.
Yu, C. A. and
Biochim.
R. A.
(ed.)
T. E. (1981) 3 (K. Folkers,
(1965)
Biochemistry
of Quinones,
(G.E.W.
Academic
Press,
"New Horizons in Biological Chemistry--Fetschaft (M. Koike, T. Nagatsu, J. Okuda and T. Ozawa, Sot. Press, Tokyo, pp. 121-134.
in "Biomedical and Clinical Aspects of Coenzyme Q," ed.), Elsevier-North Holland, Amsterdam (in press).
C. A. and Yu, L.
Yu,
in Electron Transport" eds.) Churchill, London.
L.
(1980)
(1980)
T. E. (1977)
Biochemistry
Biochem.
19,
(1977)
14 18
Res.
Commun.
3579-3585.
Biochem.
Biophys.
Biophys.
Biophys.
Acta 591,
Res. 409-420.
Commun.
BIOCHEMICAL
Vol. 99, No. 4,1981
D. E. (1961)
AND
BIOPHYSICAL
Green,
11.
Kroger,
A. and Klingenberg,
21. (1973)
Eur.
J. Biochem.
3,
358-368.
12.
Kroger,
A. and Klingenberg,
M. (1973)
Eur.
J. Biochem.
2,
313-323.
13.
Yu, C. A., Nagaoka, S., Yu, L. and King, Res. Commun. g, 1070-1078.
14.
Yu, C. A., Nagaoka, Biophys. 2, 59-70.
15.
Ohnishi,
16.
Yu,
17.
Nagaoka, press).
18.
Feher, G., Okamura, Acta 267, 222-226.
19.
Das, M. R., Connor, H. D., Keniart, J. Am. Chem. Sot. 92, 2258-2268.
20.
King, T. E. (1978) in "Membrane Proteins" P. L. Jdrgensen, and A. J. Moody, eds.), 17-31.
21.
King, ed.),
22.
Takemori,
S. and King,
T. E. (1964)
Science
23.
Takemori,
S. and King,
T. E. (1964)
J. Biol.
C. A.,
S.,
Yu, L.,
and Trumpower, Yu, L. and King,
S.,
& Physiol.
81-122.
T. E. (1978)
and King,
B. L.
4,
COMMUNICATIONS
10.
T.,
Comp. Biochem.
RESEARCH
Biochem.
T. E. (1980)
Arch.
Biophys. Biochem.
(1980)
J. Biol.
Chem. 255,
3278-3284.
T. E. (1974)
J. Biol.
Chem. 249,
4905-4910.
Yu, L. and King,
T. E. (1981)
M. Y. and McElroy,
T. E. (1981) in "Quinones Academic Press, New York
Arch.
J. D.
Biochem.
(1972)
D. S. and Freed,
1419
Biochim.
Coupling" l&,
Biophys.
J. H. (1970)
(P. Nicholls, Pergamon Press,
in Energy (in press).
Biophys.
J. V. Mbller, Oxford, pp.
(B. L. Trumpower, 852-853.
Chem. 239,
3546-3558.
(in