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Reconstitution of succinate-Q reductase
Vol. 79, No. 3, 1977
BIOCHEMICAL
RECONSTITUTION Laboratory
Received
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
OF SUCCINATE-Q REDUCTASE
C. A. Yu, L. Yu, and Tsoo E. King of Bioenergetics and Department of Chemistry State University of New York at Albany Albany, New York 12222
October
31,1977
SUMMARY--Reconstitution of succinate-Q reductase is achieved by admixing soluble succinate dehydrogenase (SDH) and ubiquinone-protein-S (QP-S), a new protein isolated from the soluble cytochrome The reconsti--b-cl complex. tuted reductase catalyzes reduction of Q by succinate. The reaction is fully sensitive to thenoyltrifluoroacetone. The reconstituted reductase (same as succinate-cytochrome 2 reductase or submitochondrial particles) does not show "low concentration ferricyanide reductase activity" as soluble dehydrogenase does. In other words, this enzymic site on SDH is occupied by QP-S. When an artificial dye, such as phenazine methosulfate or Wurster's Blue, is used as electron acceptor the rate of oxidation of succinate by SDH is not significantly changed regardless of whether the dehydrogenase is in the free or in the reconstituted succinate-Q reductase forms. Freshly
prepared
genase
possesses
quires
low
ferricyanide
concentrations
tion
exists
iron (5)
-
(Km s 10 mM) (2,
activity
Blue
phenol
(1)
the action
but not
inhibits
sulfide
(Q)l,
succinate 5 reductase
oxidation
a correlalow-fer-
(high
potential
(i.e. --
Center
use phenazine
electron
acceptors. (TTFA)
enzyme but markedly catalyzed
as well
that
needs
dyes
S-3) (6,
7)
or 2,4-dichlorophenolindo-
thenoyltrifluoroacetone soluble
type center
can also
as artificial
of the
the other
reconstitutivity,
of the HiPIP iron
dehydroOne re-
has been claimed
parameters:
ubiquinone
among others,
activities
succinate-cytochrome 1
(8),
succinate
activities.
m ?J 50 PM), while It
dehydrogenase
of inhibitors,
the artificial quantities)
3).
and the appearance
succinate
and Wurster's
to
(K
three
active
reductase
as shown by EPR technique)
In addition,
(DCIP)
following
(4)
(1)
ferricyanide
concentrations
among the
protein
reconstitutively
two distinct
high
ricyanide
soluble,
as succinate
In regard
barely (in
by reconstituted oxidase
inhibits micromolar or intact
(see Fig.
1 of
Abbreviations used: DCIP, dichlorophenolindophenol; HiPIP, high potential iron protein; PMS, phenazine methosulfate; Q, ubiquinone; QP-S, ubiquinonebinding protein in the succinate dehydrogenase region; SDH, succinate dehydrogenase; TTFA, thenoyltrifluoroacetone; and WB, Wurster's Blue.
Copyright 0 1977 by Academic Press, Inc. AN righrs of reproduction in any form reserved.
939 ISSN
0006-291X
BIOCHEMICAL
Vol. 79, No. 3, 1977 Ref.
1).
with
It
is also
half-lives
we have
binding
(hydrogen)
reports
reconstitution the locus
differences
and 8 hours, in
demonstrated (QP-S,
carrier
previously
from
exists
in the
unstable
reconstitutive
(1). of a ubi-
which
to ubiquinone
and other
can serve
(9).
This
properties
delineating
are
also
In addithe
and dehydrogenase
chain,
as an
paper
from QP-S and SDH.
dehydrogenase
MATERIALS
of air
QP-1)
reductase
respiratory
for
and isolation
called
succinate
succinate
enzyme is
respectively,
the existence
of TTFA inhibition free
the soluble
the presence
of succinate-Q
between
or as it
that
at O-4"
protein
electron
QP-S,
0.5
activities
Recently
tion,
documented
of about
and artificial
quinope
well
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
bound
to
reported.
AND METHODS
Succinate dehydrogenase (1, 7), the cytochrome b-51 complex (lo), the heart muscle preparation (ll), and Wurster's Blue (12) were prepared by previously reported methods. QP-S2 was prepared as briefly described in (9); details will be published elsewhere. The concentrations of electron acceptors were measured spectrophotometrically and the millimolar extinction coefficients (7, 12) used were 5.2 at 510 nm, 21 at 600 nm, and 1.0 at 410 nm, for Wurster's Blue, DCIP, and ferricyanide, respectively. Enzymic assays were conducted spectrophotometrically at room temperature, about 23". The reaction mixture, in a final volume of 1 ml, contains 50 mM Na-K phosphate buffer, pH 7.8; 1.5 mM KCN; 1 mg/ml bovine serum albumin; 40 mM succinate and various amounts of proper electron acceptors (cf. Ref. 7). It must be mentioned that cyanide was added by following the conventional method (see Ref. 13 for easier comparison of data appearing in earlier literature), rather than for the possible contamination of oytochrome oxidase. Indeed, all QP-S and SDH described in this paper are completely free of any cytochrome. Spectrophotometric measurements were done in a Cary spectrophotometer, model 16, with a recorder. RESULTS AND DISCUSSION Figure activity
of freshly
K3Fe(CN)6 of the
at 23".
tracing,
When this about
1A shows
the actual prepared
tracing SDH.
The specific is
preparation
13 umoles3
of the
The assay was conducted
activity,
as calculated
succinate
was simply
oxidized
admixed
5 mol QP-S per mol of SDH) and then
2 A part of Q of the and purification.
QP-S isolated
low-ferricyanide
with
with
excess
amounts
under
the
slope
mg protein. of QP-S (i.e. -same conditions
in the course
3 The range of activity is usually between 12 and 16 umoles oxidized per min per mg of SDH at room temperature.
940
350 uM
by the initial
per min per
assayed
has dissociated
reductase
of isolation
of succinate
Vol. 79, No. 3, 1977
Fig.
1.
no activity Q (Fig.
succinate-Q reductase is
(< 5%) of free
1A);
reductase activity
further
SDH.
ductase
activity
rapidly
in air
indicates
was stimulated unlike
does not (cf. -
Ref.
1).
to that
of the
functionally particles
(cf. not
only
Ref.
enzyme, time;
The slower
--l b-c 14).
reconstitute
complex
rate
(L.e. (10)
of
converted
to
ferricyanide
of succinate-Q
reductase
of Q, the reduction
as that
in the initial
free
rate
succinate-Q
re-
SDH inactivates
shown at the end of the trac-
QP-S bound or alkaline h-cl
SDH to form
941
the absence
low
of ferricyanide
The cytochrome with
so-called
reconstituted whereas
of exhaustion
of QP-S toward
cytochrome
same level
in
now being
upon the addition
decay with
ing was due to the approach The reaction
that
free
of the Formation
to the the
SDH is
site
occupied.
by the fact
Also,
SDH was observed that
and the active
evidenced
of free
this
of SDH is
of ferricyanide
mixture.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Activities of succinate-dehydrogenase and reconstituted succinate-Q reductase. (A) Ferricyanide and (B) Wurster's Blue were used as electron acceptors: 5 ~1 of freshly prepared SDH, 0.77 mg/ml, were used in the assay. In the reconstituted system, excess QP-S (5-fold of the dehydrogenase) was mixed with SDH; the concentration of SDH was also adjusted to 0.77 mgfml.
practically exogenous
BIOCHEMICAL
complex
in the reaction to)
SDH is
treated
particles
or alkaline
succinate-cytochrome
identical
treated c re-
BIOCHEMICAL
Vol. 79, No. 3, 1977
Fig.
2.
Double reciprocal reductase activity for the enzymes The concentrations Blue (B) in the concentration of the PMS systems
ductase
or succinate
ferricyanide
plots for SDH and reconstituted succinate-Q against acceptor concentrations. The conditions used were identical to those detailed in Fig. 1. of the immediate acceptors of PMS (A) and Wurster's reaction mixture are given in the plots. The DCIP in (A) was kept at constant, 45 mM. In all described in this paper, the final acceptor was DCIP.
oxidase,
reductase
respectively,
activity
by the able
fact
lB, that
to catalyze
dye reduction ductase;
Figure succinate-Q
free
reduction
the rate not
Q also
affected double
reductase
activities it
by the
resulted
formation
reductase
by SDH in
of free
decrease
significant
942
complicated are of this
of succinate-Q
SDH'and
WB and PMS assay
in a slight
succinate not the Vmax . In the PMS system V succinate was observed in reconstituted lMX
were
as
re-
the presence
of Q.
plots
toward
results,
The stimulation
of WB catalyzed
reciprocal
the low
similar
the results
15).
the
addition
abolish
succinate-Q
Ref.
confirms
of reduction
2 depicts
was used as acceptor
acceptor,
case
of WB (cf.
also
same time.
electron
In this
they
SDH and reconstituted
by exogenous
is
as the
observed.
both the
whereas
of succinate
were
but
of SDH at the
When WB (260 uM) was used shown in Fig.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
succinate-Q
systems.
in Km for increase
reconstituted
both
reductase.
When WB the dye but PMS in Km and It
should
be
Vol. 79, No. 3, 1977
TABLE I.
BIOCHEMICAL
Km and "max of Succinate
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Dehydrogenase
and Reconstituted
Succinate-
Q Reductase. Electron Preparations
Succ.. + PMS-DCIP V
Km Succinate
VIIBX
0.3
18
reductase
0.9
22
is
expressed
temperature
mentioned less
artificial
cinate-Q
reductase
It
is
ase is
known
drial
particles,
acceptors
using that
but
not
enzyme for
shows the inhibition
90% of activity
just
like
the enzyme bound
ly unaffected
which
identical
behavior
1 of Ref. to that
succinate
oxidation
cytochrome
form which (1).
the
0.7
41.7
at room
to locate
of SDH and suc-
when
reacts
only
artificial reductase
the TTFA locus.
On the other dehydrogenase
Reconstituted
or submitochon-
with
Figure
reductase
by TTFA in micromolar
free
the dehydrogen-
succinate-Q
succinate-Q
hand, activity
of inhibitor succinate-Q
of Q.
of Q present
-c reductase
Reconstituted
the concentration
of free
41.7
of Q regard-
to the amount
acceptors.
to particles.
1).
1.1
by the presence
electron
was inhibited
measures
affected
of Km and V,,,
in soluble dyes
V max
In the case of succin-
the data
such as in
by TTFA even if
as 3 mM (See Fig.
is used.
of TTFA of reconstituted
than
by the presence
proportionally
experimentation
More
to PMS reaction
affected
to be greatly
TTFA inhibits form"
21.6
per mg SDH per minute
acceptor
different
such as phenazine
is an ideal
not
I summerizes
the ucomplex
in
SDH is
electron
Table
Km
in mM.
of the dye decreases
the system.
Succ. + WB
VIllaX
Km
0.035
of dye reduced expressed
K PMS was found m
reductase,
The Km value in
Km is
PMS the Km for
that
of which
ate-Q
as umoles
(23').
Succ. + Q-DCIP
max
dehydrogenase
Succinate-Q
Acceptors
activity.
concentration the succinate was completeused was as high reductase
showed
SDH when PMS was used as the electron
943
3A
Vol. 79, No. 3, 1977
Fig.
3.
BIOCHEMICAL
Inhibition of thenoyltrifluoroacetone of reconstituted succinate-Q reductase activity. (A) was the titration of TTFA using Q (15 mM) and PMS (1.8 mM) as electron acceptors, and (B) was the double I reciprocal plot of succinate-Q reactivity in -vs. Q concentration the presence and absence of TTFA.
acceptor.
When reconstituted
concentrations inhibition
of Q in was observed.
Figure
of Q and the
the inhibitor.
An inhibitor
should
refer
be mentioned
to only
Recently, the enzymic Vinogradov
Ackrell tion resolve
all
(8)
using
--et al.
found between
that
acceptor
various
competitive plots
of the
and absence to be around
of 30 ).M.
of Q and TTFA used here of the solubility than
these
of the
WB and PMS systems
as that difference
two dye systems.
regarding
for
oxidation using
re-
values.
8) have appeared
SDH catalyzes
no significant these
was calculated
(16,
under
reciprocal
in the presence
be smaller
articles
reported
the double
Because
might
WB as electron
(16)
of succinate
Ki,
Vmax, of SDH using
et al.
was assayed
the concentrations
two controversial
as fast
activity
constant,
concentrations
assay.
of succinate PMS; whereas,
in the rate Our results
of oxidaautomatically
the disparity. On the other
effect
3B shows
concentration.
activity,
reductase
of 10 pM and 56 nM TTFA,
enzymic
that
apparent
the true
agents,
twice
succinate-Q
the presence
concentration
It
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of "membrane
hand,
our
results
environment"
give on SDH.
944
no support Actually
to the claim the
so-called
of the "membrane
Vol. 79, No. 3, 1977
is
environmentv dehydrogenase amount
BIOCHEMICAL
just
no more than
combines
with
possibility
for
structure is not
likely.
plained cinate
QP-S is
"membrane
environment"
In conclusion, with
well
"membrane
defined
in
for
environmentn
inhibition
and the reaction
themselves
cannot
directly
rate
arguing
of reconstitution
SDH and QP-S not but
its
acceptor
than
only
a small the
in a "membrane-like" recombination
with
SDH
of the dyes can be exand thus for
oxidized
suc-
the requirement
of a
such a reaction.
the success soluble
after
electron
succinate
QP-S contains
reductase
(17)
way rather
after
was made in detergent,
the reduction
the native
in a more effective
isolated
of succinate-Q
environment"
The increase
since
Since
exhibited
and the protein
the formation
of a "membrane
the behavior
QP-S.
(< 20%) of phospholipid4
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
also
only
unequivocally
locus interact
of DCIP (or with
of succinate-Q resolves
reductase
the "mystery"
defines
the sites
of TTFA
related
compounds)
which
of
SDH.
ACKNOWLEDGMENTS Health
This work was supported by grants from the National and the American Heart Association, Northeastern
Institutes New York
of Chapter,
Inc.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11.
King, T. E. (1966) Adv. Enzymol. 2&, 155-236. Vinogradov, A. D., Gavrikova, E. V., and Goloveshkina, V. G. (1975) Biochem. Biophys. Ras. Commun. 65, 1264-1269. Kettman, J. R. (1967) Ph. D. Thesis, Oregon State University, Corvallis, Oregon. Vinogradov, A. D., Ackrell, B. A. C., and Singer, T. P. (1975) Biochem. Biophys. Res. Commun. 67, 803-809. King, T. E., Ohnishi, T., Winter, D. B., and Wu, J. T. (1976) in Iron and Copper Proteins (Yasunobu, K. T., Mower, H. F., and HayaisK, O., eds.) pp. 182-227, Plenum Publishing Corp., New York. King, T. E. (1963) J. Biol. Chem. 238, 4032-4036. King, T. E. (1967) Methods Enzymol. lo, 322-331. Vinogradov, A. D., Goloveshkina, V. G., and Gavrikova, E. V. (1977) FEBS Lett. 12, 235-238. Yu, C. A., Yu, L., and King, T. E. (1977) Biochem. Biophys. Res. Commun. 78, 259-265. Yu, C. A., Yu, L., and King, T. E. (1974) J. Biol. Chem. 249, 4905-4910. King, T. E. (1967) Methods Enzymol. 1.0, 202-208.
4 Accurate
determination of lipid requires large amounts of the sample, thus 20% is the maximal value. More likely it is much smaller than the cited value when sufficient sample is available for assay.
945
Vol. 79, No. 3, 1977
12. 13. 14. 15. 16. 17.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
King, T. E., Howard, R. L., Kettman, J., Jr., Hegdekar, B. M., Kuboyama, M, Nickel, K. S., and Possehl, E. A. (1966) a Flavin and Flavoproteins (Slater, E. C., ed.) pp. 441-481, Elsevier Publishing Co., Amsterdam. Bemath, P., and Singer, T. P. (1962) Methods Enzymol. 5, 597-614. Keilin, D., and King, T. E. (1960) Proc. Roy. Sot., London, Series B, 152, 163-187. Mustafa, M. G., Cowger, M. L., Labbe, R. F., and King, T. E. (1968) J. Biol. Chem. 243, 1908-1918. Ackrell, B. A. C., Coles, C. J., and Singer, T. P. (1977) FEBS Lett. 75, 249-253. Ackrell, B. A. C., Kearney, E. B., and Singer, T. P. (1977) J. Biol. Chem. 252, 1582-1588.
946
BIOCHEMICAL
RECONSTITUTION Laboratory
Received
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
OF SUCCINATE-Q REDUCTASE
C. A. Yu, L. Yu, and Tsoo E. King of Bioenergetics and Department of Chemistry State University of New York at Albany Albany, New York 12222
October
31,1977
SUMMARY--Reconstitution of succinate-Q reductase is achieved by admixing soluble succinate dehydrogenase (SDH) and ubiquinone-protein-S (QP-S), a new protein isolated from the soluble cytochrome The reconsti--b-cl complex. tuted reductase catalyzes reduction of Q by succinate. The reaction is fully sensitive to thenoyltrifluoroacetone. The reconstituted reductase (same as succinate-cytochrome 2 reductase or submitochondrial particles) does not show "low concentration ferricyanide reductase activity" as soluble dehydrogenase does. In other words, this enzymic site on SDH is occupied by QP-S. When an artificial dye, such as phenazine methosulfate or Wurster's Blue, is used as electron acceptor the rate of oxidation of succinate by SDH is not significantly changed regardless of whether the dehydrogenase is in the free or in the reconstituted succinate-Q reductase forms. Freshly
prepared
genase
possesses
quires
low
ferricyanide
concentrations
tion
exists
iron (5)
-
(Km s 10 mM) (2,
activity
Blue
phenol
(1)
the action
but not
inhibits
sulfide
(Q)l,
succinate 5 reductase
oxidation
a correlalow-fer-
(high
potential
(i.e. --
Center
use phenazine
electron
acceptors. (TTFA)
enzyme but markedly catalyzed
as well
that
needs
dyes
S-3) (6,
7)
or 2,4-dichlorophenolindo-
thenoyltrifluoroacetone soluble
type center
can also
as artificial
of the
the other
reconstitutivity,
of the HiPIP iron
dehydroOne re-
has been claimed
parameters:
ubiquinone
among others,
activities
succinate-cytochrome 1
(8),
succinate
activities.
m ?J 50 PM), while It
dehydrogenase
of inhibitors,
the artificial quantities)
3).
and the appearance
succinate
and Wurster's
to
(K
three
active
reductase
as shown by EPR technique)
In addition,
(DCIP)
following
(4)
(1)
ferricyanide
concentrations
among the
protein
reconstitutively
two distinct
high
ricyanide
soluble,
as succinate
In regard
barely (in
by reconstituted oxidase
inhibits micromolar or intact
(see Fig.
1 of
Abbreviations used: DCIP, dichlorophenolindophenol; HiPIP, high potential iron protein; PMS, phenazine methosulfate; Q, ubiquinone; QP-S, ubiquinonebinding protein in the succinate dehydrogenase region; SDH, succinate dehydrogenase; TTFA, thenoyltrifluoroacetone; and WB, Wurster's Blue.
Copyright 0 1977 by Academic Press, Inc. AN righrs of reproduction in any form reserved.
939 ISSN
0006-291X
BIOCHEMICAL
Vol. 79, No. 3, 1977 Ref.
1).
with
It
is also
half-lives
we have
binding
(hydrogen)
reports
reconstitution the locus
differences
and 8 hours, in
demonstrated (QP-S,
carrier
previously
from
exists
in the
unstable
reconstitutive
(1). of a ubi-
which
to ubiquinone
and other
can serve
(9).
This
properties
delineating
are
also
In addithe
and dehydrogenase
chain,
as an
paper
from QP-S and SDH.
dehydrogenase
MATERIALS
of air
QP-1)
reductase
respiratory
for
and isolation
called
succinate
succinate
enzyme is
respectively,
the existence
of TTFA inhibition free
the soluble
the presence
of succinate-Q
between
or as it
that
at O-4"
protein
electron
QP-S,
0.5
activities
Recently
tion,
documented
of about
and artificial
quinope
well
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
bound
to
reported.
AND METHODS
Succinate dehydrogenase (1, 7), the cytochrome b-51 complex (lo), the heart muscle preparation (ll), and Wurster's Blue (12) were prepared by previously reported methods. QP-S2 was prepared as briefly described in (9); details will be published elsewhere. The concentrations of electron acceptors were measured spectrophotometrically and the millimolar extinction coefficients (7, 12) used were 5.2 at 510 nm, 21 at 600 nm, and 1.0 at 410 nm, for Wurster's Blue, DCIP, and ferricyanide, respectively. Enzymic assays were conducted spectrophotometrically at room temperature, about 23". The reaction mixture, in a final volume of 1 ml, contains 50 mM Na-K phosphate buffer, pH 7.8; 1.5 mM KCN; 1 mg/ml bovine serum albumin; 40 mM succinate and various amounts of proper electron acceptors (cf. Ref. 7). It must be mentioned that cyanide was added by following the conventional method (see Ref. 13 for easier comparison of data appearing in earlier literature), rather than for the possible contamination of oytochrome oxidase. Indeed, all QP-S and SDH described in this paper are completely free of any cytochrome. Spectrophotometric measurements were done in a Cary spectrophotometer, model 16, with a recorder. RESULTS AND DISCUSSION Figure activity
of freshly
K3Fe(CN)6 of the
at 23".
tracing,
When this about
1A shows
the actual prepared
tracing SDH.
The specific is
preparation
13 umoles3
of the
The assay was conducted
activity,
as calculated
succinate
was simply
oxidized
admixed
5 mol QP-S per mol of SDH) and then
2 A part of Q of the and purification.
QP-S isolated
low-ferricyanide
with
with
excess
amounts
under
the
slope
mg protein. of QP-S (i.e. -same conditions
in the course
3 The range of activity is usually between 12 and 16 umoles oxidized per min per mg of SDH at room temperature.
940
350 uM
by the initial
per min per
assayed
has dissociated
reductase
of isolation
of succinate
Vol. 79, No. 3, 1977
Fig.
1.
no activity Q (Fig.
succinate-Q reductase is
(< 5%) of free
1A);
reductase activity
further
SDH.
ductase
activity
rapidly
in air
indicates
was stimulated unlike
does not (cf. -
Ref.
1).
to that
of the
functionally particles
(cf. not
only
Ref.
enzyme, time;
The slower
--l b-c 14).
reconstitute
complex
rate
(L.e. (10)
of
converted
to
ferricyanide
of succinate-Q
reductase
of Q, the reduction
as that
in the initial
free
rate
succinate-Q
re-
SDH inactivates
shown at the end of the trac-
QP-S bound or alkaline h-cl
SDH to form
941
the absence
low
of ferricyanide
The cytochrome with
so-called
reconstituted whereas
of exhaustion
of QP-S toward
cytochrome
same level
in
now being
upon the addition
decay with
ing was due to the approach The reaction
that
free
of the Formation
to the the
SDH is
site
occupied.
by the fact
Also,
SDH was observed that
and the active
evidenced
of free
this
of SDH is
of ferricyanide
mixture.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Activities of succinate-dehydrogenase and reconstituted succinate-Q reductase. (A) Ferricyanide and (B) Wurster's Blue were used as electron acceptors: 5 ~1 of freshly prepared SDH, 0.77 mg/ml, were used in the assay. In the reconstituted system, excess QP-S (5-fold of the dehydrogenase) was mixed with SDH; the concentration of SDH was also adjusted to 0.77 mgfml.
practically exogenous
BIOCHEMICAL
complex
in the reaction to)
SDH is
treated
particles
or alkaline
succinate-cytochrome
identical
treated c re-
BIOCHEMICAL
Vol. 79, No. 3, 1977
Fig.
2.
Double reciprocal reductase activity for the enzymes The concentrations Blue (B) in the concentration of the PMS systems
ductase
or succinate
ferricyanide
plots for SDH and reconstituted succinate-Q against acceptor concentrations. The conditions used were identical to those detailed in Fig. 1. of the immediate acceptors of PMS (A) and Wurster's reaction mixture are given in the plots. The DCIP in (A) was kept at constant, 45 mM. In all described in this paper, the final acceptor was DCIP.
oxidase,
reductase
respectively,
activity
by the able
fact
lB, that
to catalyze
dye reduction ductase;
Figure succinate-Q
free
reduction
the rate not
Q also
affected double
reductase
activities it
by the
resulted
formation
reductase
by SDH in
of free
decrease
significant
942
complicated are of this
of succinate-Q
SDH'and
WB and PMS assay
in a slight
succinate not the Vmax . In the PMS system V succinate was observed in reconstituted lMX
were
as
re-
the presence
of Q.
plots
toward
results,
The stimulation
of WB catalyzed
reciprocal
the low
similar
the results
15).
the
addition
abolish
succinate-Q
Ref.
confirms
of reduction
2 depicts
was used as acceptor
acceptor,
case
of WB (cf.
also
same time.
electron
In this
they
SDH and reconstituted
by exogenous
is
as the
observed.
both the
whereas
of succinate
were
but
of SDH at the
When WB (260 uM) was used shown in Fig.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
succinate-Q
systems.
in Km for increase
reconstituted
both
reductase.
When WB the dye but PMS in Km and It
should
be
Vol. 79, No. 3, 1977
TABLE I.
BIOCHEMICAL
Km and "max of Succinate
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Dehydrogenase
and Reconstituted
Succinate-
Q Reductase. Electron Preparations
Succ.. + PMS-DCIP V
Km Succinate
VIIBX
0.3
18
reductase
0.9
22
is
expressed
temperature
mentioned less
artificial
cinate-Q
reductase
It
is
ase is
known
drial
particles,
acceptors
using that
but
not
enzyme for
shows the inhibition
90% of activity
just
like
the enzyme bound
ly unaffected
which
identical
behavior
1 of Ref. to that
succinate
oxidation
cytochrome
form which (1).
the
0.7
41.7
at room
to locate
of SDH and suc-
when
reacts
only
artificial reductase
the TTFA locus.
On the other dehydrogenase
Reconstituted
or submitochon-
with
Figure
reductase
by TTFA in micromolar
free
the dehydrogen-
succinate-Q
succinate-Q
hand, activity
of inhibitor succinate-Q
of Q.
of Q present
-c reductase
Reconstituted
the concentration
of free
41.7
of Q regard-
to the amount
acceptors.
to particles.
1).
1.1
by the presence
electron
was inhibited
measures
affected
of Km and V,,,
in soluble dyes
V max
In the case of succin-
the data
such as in
by TTFA even if
as 3 mM (See Fig.
is used.
of TTFA of reconstituted
than
by the presence
proportionally
experimentation
More
to PMS reaction
affected
to be greatly
TTFA inhibits form"
21.6
per mg SDH per minute
acceptor
different
such as phenazine
is an ideal
not
I summerizes
the ucomplex
in
SDH is
electron
Table
Km
in mM.
of the dye decreases
the system.
Succ. + WB
VIllaX
Km
0.035
of dye reduced expressed
K PMS was found m
reductase,
The Km value in
Km is
PMS the Km for
that
of which
ate-Q
as umoles
(23').
Succ. + Q-DCIP
max
dehydrogenase
Succinate-Q
Acceptors
activity.
concentration the succinate was completeused was as high reductase
showed
SDH when PMS was used as the electron
943
3A
Vol. 79, No. 3, 1977
Fig.
3.
BIOCHEMICAL
Inhibition of thenoyltrifluoroacetone of reconstituted succinate-Q reductase activity. (A) was the titration of TTFA using Q (15 mM) and PMS (1.8 mM) as electron acceptors, and (B) was the double I reciprocal plot of succinate-Q reactivity in -vs. Q concentration the presence and absence of TTFA.
acceptor.
When reconstituted
concentrations inhibition
of Q in was observed.
Figure
of Q and the
the inhibitor.
An inhibitor
should
refer
be mentioned
to only
Recently, the enzymic Vinogradov
Ackrell tion resolve
all
(8)
using
--et al.
found between
that
acceptor
various
competitive plots
of the
and absence to be around
of 30 ).M.
of Q and TTFA used here of the solubility than
these
of the
WB and PMS systems
as that difference
two dye systems.
regarding
for
oxidation using
re-
values.
8) have appeared
SDH catalyzes
no significant these
was calculated
(16,
under
reciprocal
in the presence
be smaller
articles
reported
the double
Because
might
WB as electron
(16)
of succinate
Ki,
Vmax, of SDH using
et al.
was assayed
the concentrations
two controversial
as fast
activity
constant,
concentrations
assay.
of succinate PMS; whereas,
in the rate Our results
of oxidaautomatically
the disparity. On the other
effect
3B shows
concentration.
activity,
reductase
of 10 pM and 56 nM TTFA,
enzymic
that
apparent
the true
agents,
twice
succinate-Q
the presence
concentration
It
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of "membrane
hand,
our
results
environment"
give on SDH.
944
no support Actually
to the claim the
so-called
of the "membrane
Vol. 79, No. 3, 1977
is
environmentv dehydrogenase amount
BIOCHEMICAL
just
no more than
combines
with
possibility
for
structure is not
likely.
plained cinate
QP-S is
"membrane
environment"
In conclusion, with
well
"membrane
defined
in
for
environmentn
inhibition
and the reaction
themselves
cannot
directly
rate
arguing
of reconstitution
SDH and QP-S not but
its
acceptor
than
only
a small the
in a "membrane-like" recombination
with
SDH
of the dyes can be exand thus for
oxidized
suc-
the requirement
of a
such a reaction.
the success soluble
after
electron
succinate
QP-S contains
reductase
(17)
way rather
after
was made in detergent,
the reduction
the native
in a more effective
isolated
of succinate-Q
environment"
The increase
since
Since
exhibited
and the protein
the formation
of a "membrane
the behavior
QP-S.
(< 20%) of phospholipid4
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
also
only
unequivocally
locus interact
of DCIP (or with
of succinate-Q resolves
reductase
the "mystery"
defines
the sites
of TTFA
related
compounds)
which
of
SDH.
ACKNOWLEDGMENTS Health
This work was supported by grants from the National and the American Heart Association, Northeastern
Institutes New York
of Chapter,
Inc.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11.
King, T. E. (1966) Adv. Enzymol. 2&, 155-236. Vinogradov, A. D., Gavrikova, E. V., and Goloveshkina, V. G. (1975) Biochem. Biophys. Ras. Commun. 65, 1264-1269. Kettman, J. R. (1967) Ph. D. Thesis, Oregon State University, Corvallis, Oregon. Vinogradov, A. D., Ackrell, B. A. C., and Singer, T. P. (1975) Biochem. Biophys. Res. Commun. 67, 803-809. King, T. E., Ohnishi, T., Winter, D. B., and Wu, J. T. (1976) in Iron and Copper Proteins (Yasunobu, K. T., Mower, H. F., and HayaisK, O., eds.) pp. 182-227, Plenum Publishing Corp., New York. King, T. E. (1963) J. Biol. Chem. 238, 4032-4036. King, T. E. (1967) Methods Enzymol. lo, 322-331. Vinogradov, A. D., Goloveshkina, V. G., and Gavrikova, E. V. (1977) FEBS Lett. 12, 235-238. Yu, C. A., Yu, L., and King, T. E. (1977) Biochem. Biophys. Res. Commun. 78, 259-265. Yu, C. A., Yu, L., and King, T. E. (1974) J. Biol. Chem. 249, 4905-4910. King, T. E. (1967) Methods Enzymol. 1.0, 202-208.
4 Accurate
determination of lipid requires large amounts of the sample, thus 20% is the maximal value. More likely it is much smaller than the cited value when sufficient sample is available for assay.
945
Vol. 79, No. 3, 1977
12. 13. 14. 15. 16. 17.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
King, T. E., Howard, R. L., Kettman, J., Jr., Hegdekar, B. M., Kuboyama, M, Nickel, K. S., and Possehl, E. A. (1966) a Flavin and Flavoproteins (Slater, E. C., ed.) pp. 441-481, Elsevier Publishing Co., Amsterdam. Bemath, P., and Singer, T. P. (1962) Methods Enzymol. 5, 597-614. Keilin, D., and King, T. E. (1960) Proc. Roy. Sot., London, Series B, 152, 163-187. Mustafa, M. G., Cowger, M. L., Labbe, R. F., and King, T. E. (1968) J. Biol. Chem. 243, 1908-1918. Ackrell, B. A. C., Coles, C. J., and Singer, T. P. (1977) FEBS Lett. 75, 249-253. Ackrell, B. A. C., Kearney, E. B., and Singer, T. P. (1977) J. Biol. Chem. 252, 1582-1588.
946