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Membrane-bound glutathione peroxidase-like activity in mitochondria
Vol.
96, No.
September
1, 1980
8lOCHEMlCAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Pages 85-91
16, 1980
MEMBRANE-BOUND GLUTATHIONE Aspandiar
PEROXIDASE-LIKE
G. Ratki*l
ACTIVITY
and Charles
IN MITOCHONDRIA
E. Myers+
*Radiobiology Division, Tufts-New England Medical Center Hospital, 171 Harrison Avenue, Boston, Massachusetts 02111, and +Clinical Pharmacology Branch, National Cancer Institute Bethesda, Maryland 20205 Received
July
21,198O
SUMMARY
A membrane-bound glutathione peroxidase-like activity has been detected in liver and cardiac mitochondrial membrane. This enzyme activity differs from the cytosol and mitochondrial matrix selenium-dependent glutathione peroxidase in that it is membrane bound, sensitive to sonication and tritonX-100, and is unaffected by prolonged feeding of a selenium-free diet. This mitochondrial membrane-bound enzyme activity differs from the glutathione-stransferases which exhibit glutathione peroxidase activity in that it is capable of utilizing both cumene hydroperoxide and hydrogen peroxide as substrates. Digitonin fractionation studies indicate that this enzyme is not located in either inner or outer mitochondrial membrane but rather within inter-membrane space. This newly described membrane-bound enzyme activity may play an important role in the maintenance of cardiac mitochondrial integrity in that mitochondrial matrix does not contain glutathione peroxidase. INTRODUCTION As part
of our
investigation
rubicin
cardiac
toxicity
H202 in
cardiac
mitochondria.
mitochondrial Cardiac
H202/min/mg to result oxidation, for lipid
in
turn, in
peroxidation
of glutathione
and "high
swelling amplitude"
(11).
peroxidation the
and
is
H202 are
to
lipids
function
and has
of liver swelling
Detoxification
of
of
4 (3,4).
0.3-0.6
nmol
and H202 is known (7,8).
mitochondria are
state
produce
of superoxide
of
byproducts
in
membrane
in doxo-
detoxification
greatest
estimated
production
mitochondrial
amplitude"
anion
been
of mitochondrial
peroxidase for
This
of lipid
re-examined
production
have
fact,
affects
"high
we have
their
(3,5,6).
in peroxidation
role
Superoxide
and in
protein
example,
1Requests Institute,
(1,2),
metabolism
mitochondria,
of the
lessened superoxide
been
Lipid
per-
implicated, (9,lO).
by the and
reprints should be addressed to: A. G. Ratki, National Building 10, Room 6N119, Bethesda, Maryland 20205.
Both addition hydrogen Cancer
0006-291X/80/170085-07$01.00/0 85
Copyright 0 1980 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol.
96, No.
peroxide
by mitochondria
Mitochondria (13), are
BIOCHEMICAL
1, 1980
have
and all
has thus
been
shown
to
selenium-dependent
contained
in hepatic
of cardiac
examined,
especially
with
In the present
study,
matrix.
both the
the
described
reported
a glutathione
with
catalase
These
enzymes
Peroxide
detox-
with
activity.
mitochondria
lack
in
some properties
mitochondrial activity
which
glutathione
peroxidase
the selenium-
liver
peroxidase
selenium-dependent
glutathione-S-transferases
(12),
(14-16).
peroxidase
cardiac
space
interest.
have not been as comprehensively
previously
detected
considerable
(12,13-16).
to glutathione
inter-membrane
previously
matrix
COMMUNICATIONS
dismutase
peroxidase
we show that
we have
of
super-oxide
mitochondria
regard
RESEARCH
a subject
contain
peroxidase
Instead,
the mitochondrial
been
mitochondrial
mechanisms
glutathione
BIOPHYSICAL
glutathione
ification
dependent
AND
within
differ
from
peroxidase
and
activity.
METHODS AND MATERIAL CDFl male mice were obtained from Dublin Laboratories, Dublin, VA, and kept on selenium-containing or selenium-free diet as described earlier and liver subcellular fractions and mitochondrial sonication (2). Cardiac and triton-X-100 treatment were done as described in legends to tables. Glutathione peroxidase activity was determined according to Lawrence and Burk (17) with some modifications as described in the legend to Table I. Protein was determined by the method of Lowry et al (18). For most of the glutathione peroxidase assays, physiologic pH was used in order to ensure that the ratio of activities in the various fractions were measured under a reasonable approximation of in vivo conditions. In the digitonin experiments, in order to gain greater sensitivity, the membrane-bound enzyme was assayed at its pH optimum of 8.0. were
RESULTS AND DISCUSSION Of the one,
the
hydrogen
enzymes
known
selenium-dependent peroxide
and
ary
hand,
selenium
cumene
tathione mals results
peroxidase
utilize For
(Table
these
exhibit
as
peroxide
reasons,
animals
substrates
thatmitochondria
to
and are not
utilize
both The
activity,
affected
tissue
on
by diet-
distribution
peroxides are
only
(17,18-21).
peroxidase
in cardiac both
activity,
able
the subcellular
using
86
is
glutathione
I) was measured
mice reveal
peroxidase
peroxidase,
hydrogen
and in selenium-deficient from control
glutathione
hydroperoxide
which
cannot
(23,24).
exhibit glutathione
glutathione-S-transferases the other
to
of glu-
from control as substrates.
the richest
intracellu-
aniThe
Vol.
96, No.
1, 1980
Table
BIOCHEMICAL
I.
AND
BIOPHYSICAL
COMMUNICATIONS
SUBCELLULAR DISTRIBUTION OF GLIJTATHIONE PEROXIDASE ACTIVITY IN HEART MUSCLE WITH DIFFERENT SUBSTRATES IN CONTROL AND SELENIUM-DEFICIENT CDFl MICE CONTROL
Cell
RESEARCH
Hydrogen Peroxide As Substrate (nmoles/min/mg
Fraction
SELENIUM-DEFICIENT Cumene Hydrogen HydroPeroxide Peroxide As As Substrate Substrate (nmoles/min/mg protein)
Cumene HydroPeroxide As Substrate protein)
Homogenate
5.45
7.00
5.78
9.70
Pellet
5.31
6.96
7.51
8.38
Mitochondria
10.30
9.48
Microsome
0
0
1.22
1.86
4.33
5.11
1.28
2.85
Soluble
11.25
10.80
Subcellular fractionation was done by preparing 10% heart homogep ate in 250 mM sucrose, 1 mM Tris, 10 mM EDTA, pH 7.2, in a Brinkmann model PCU-2-110 Polytron 3 times for 5 set at 5.5 settings with cooling in between cycles. After sedimentation of the nuclear fraction (700 x G for 10 min), the supernatant was centrifuged at 10,000 x G for 15 mln to sediment mitochondria. The post-mitochondrial supernatant was centrifuged at 105,000 x G for 60 min to sediment microsomes. Nuclear, mitochondrial, and microsomal pellets were resuspended in the initial buffer. Glutathione peroxidase activity was determined by the decrease in absorbance at 340 w by incubating enzyme in 100 mM Tris, 3 mM EDTA, pH 7.0, 1.2 units glutathione reductase, 0.25 mM GSH, 3.0 mM NaN3, 0.25 mM NADPH, and 0.04 ml4 H202 or 0.075 mM cumene hydroperoxide in 1 ml final volume. Blank reactions with the enzyme source replaced by distilled water were subThe activity is expressed as nmoles NADPH tracted from each assay. oxidized/ min/mg protein using the extinction coefficient for NADPH Succinate-cytochromecreductase activity of 6.22 x lo3 mol-l cm-l. and rotenone-insensitive NADH-cytochrome 2 reductase activity were determined as mitochondrial and microsomal marker enzymes, respectively.
lar
source
twice
that
(Table
I,
tion is
of
glutathione
of the homogenate columns
glutathione less
(Table
than I,
peroxidase
activity
sults
suggest
which
is
more
3 and 4) did
30% of that 1). showed
I,
In
contrast,
a slight
to
with
effect
mitochondrial
peroxidase
effects
87
of
on the
with
selenium
deficiency
soluble
frac-
where
activity
hydrogen
peroxide
glutathione selenium
activity
Selenium
dependent,
mice when assayed
with
a specific
1 and 2).
be selenium
increase
the
heart
expected
of glutathione to
the
columns
the
from control
the presence resistant
have known
peroxidase,
column
cific
(Table
in
peroxidase
deficiency. activity deficiency
spe-
These
re-
in mitochondria than
is
the
Vol.
96, No.
1, 1980
previously
BIOCHEMICAL
described
to utilize
both
Previous
cytosolic cumene
studies
(15,24).
in liver
sonication
(14)
chondrial glutathione the
into
of mitochondria
activity.
selenium-deficient suggest bound
that
but less
Because for
liver
these
we have
X-100
treatment
results
(Table
supernatant.
In contrast,
also
found
selenium-deficient
for
post-sonication
is
free
of glutamembrane
Triton-X-100 complete
treatment loss
of
090%)
of mitochondria
from
These results
enzyme but have
deficiency
so sharply
and
the
matrix
those
with
is
a membranesensitive
to both confirm
to
remains
most
mice.
in the
selenium-deficient
after
sonication Furthermore,
of the matrix
88
activity
the
in the triton-
from
and liver
post-treatment
post-treatment
mice,
However,
is
sonication
in
activity
pellet
both peroxidase
little
enzyme.
reported
and
glutathione in activity
matrix
sonication that
increase
from
previously
of the enzyme activity
by the
control
mice,
most
Our results
release
of this
from
the
reported
in enzyme activity.
mitochondria
B).
in the membrane
of mitochondria
mito-
mitochondrial
that
treatment
by
the
mitochondrial
in nearly
the matrix
where
mitochondria
dependency
disrupt
paralleled
contains
by selenium
liver II
as reflected
liver
lack
contrast
subjected
mitochondria
selenium
which
drop
mitochondria
be liberated
Triton-X-100
(14-16,24)
treatment
of
should
mitochondrial
cardiac
that
existence
so to sonication.
triton-X-100
ernate
it
of
able
substrate.
the
the
of which
A shows
resulted
unaffected
mitochondria
matrix,
mice
mitochondria is
II
enzyme
mice gave a similar
enzyme which
triton-X-100
Table
activity.
cardiac
liver
50% of the enzyme activity.
control
peroxidase
from
behavior
to see if
The pellet,
about
from
the
reason,
a matrix
in
still
as
only
located
both
is
peroxide
reported
liberated
(15,16,24),
enzyme.
possesses
glutathione
been
was assessed
which
peroxidase
fragments,
has
this
mitochondrial
supernatant thione
For
peroxidase
liver
peroxidase
and triton-X-100
membrane.
have
COMMUNICATIONS
but which
hydrogen
mitochondria
enzyme
RESEARCH
peroxidase and
glutathione
This
BIOPHYSICAL
glutathione
hydroperoxide
of a seleniunrdependent matrix
AND
sup-
confirming
the
some enzyme activity and triton-X-100
in
liver is
lost
treatment
mitochondria but
is
29.3%
from of the
Vol.
96, No.
BIOCHEMICAL
1, 1980
Table
II.
AND
EFFECTS OF SONICATION LIVER MITOCHONDRIAL
BIOPHYSICAL
RESEARCH
AND TRITON-X-100 ON CARDIAC AND GLUTATHIONE PEROXIDASE ACTIVITY SONICATION* (nnoles/min/mg
A.
COMMUNICATIONS
TRITON-X-100' protein)
Heart
Intact
mitochondria Post-treatment Post-treatment
Se-deficient intact Post-treatment Post-treatment B.
11.06 0 5.63
supernatant pellet
12.65 0 0.99
mitochondria supernatant pellet
14.41 0.21 2.64
Liver
Intact
mitochondrial Post-treatment Post-treatment
25.45 74.60 24.55
supernatant pellet
Se-deficient intact Post-treatment Post-treatment
25.45 61.15 9.76
mitochondria supernatant pellet
13.99 2.84 4.10
*Mitochondria, 2 to 6 mg/ml protein, were sonicated 10 set x 3 by Branson Sonifier Cell Disruptor 185 with microtip, setting control output on 6 and meter reading 42-44 watts/second, and were sedimented at 105,000 x G for 60 min to separate the mitochondrial membrane pellet, which was resuspended in 250 mM sucrose, 1 mM Tris, 10 mM EDTA, pH 7.2. +To the mitochondrial suspension, 1 to 2 mg/ml, in 250 mM sucrose, 1 mM Tris, 10 mM EDTA, pH 7.2 was added triton-X-100 in 50 mM Tris, 1.5 ml4 EDTA, pH 7.0 to final concentration 0.5% and incubated at 0' for 10 min. The suspension was sedimented at 105,000 x G for 60 min to separate mitochondrial membrane pellet which was resuspended in 250 mM sucrose, 1 mM Tris, 10 mM EDTA, pH 7.2. 110% liver homogenate in 250 mM sucrose, 1 mM Tris, 10 ml4 EDTA, pH 7.2 was centrifuged at 600 x G for 10 min to sediment nuclei. The post-nuclei supernatant was centrifuged at 8,500 x G for 12 min to sediment mitochondria, suspended in 250 mM sucrose, 1 mM Tris, 10 mM EDTA, pH 7.2 to 4-6 mg/ml.
original
mitochondrial
persists.
These
membrane-bound
glutathione
results
consist becane
the
of
treatment contents
the
a standard
the
as
the
localizing
activity
well
as
located outer
membrane
the
previously
the
pellet
possess
a
described
in the matrix.
and
membrane yields
and matrix.
enzyme activity
in
may also
mitochondrial space
89
found
mitochondria
inter-membrane
mitochondrial
one for
liver
peroxidase
disrupts of
inner
that
peroxidase
glutathione
Digitonin releases
suggest
glutathione
selenium-dependent
peroxidase
within
and
mitoplasts This
thus which
technique
the mitochondrial
has
Vol.
96, No.
1, 1980
Table
BIOCHEMICAL
III.
AND
BIOPHYSICAL
RESEARCH
EFFECT OF DIGITONIN TREAlMENT ON CARDIAC GLDTATHIONE PEROXIDASE ACTIVITY
MITOCHONDRIAL
SPECIFIC (nmoles/min/mg Intact
1.59
membrane
Inter-membrane Inner
26.3
space
membrane
1.61
1.89
Matrix
Mitochondria
were
isolated
Digitonin fractionation except that buffer and 250 mM sucro.se, athione peroxidase Table I in Tris-EDTA,
membrane.
Table
III As
inter-membrane
space.
found located
It
remains
truly
pool cytosol
selenium
which
turns
complex
analysis
in
we have
in liver
independent
matrix enzyme
Cardiac while
localized
in
to the
of
addition
to
the
glutathione
peroxidase
a glutathione
peroxidase
mitochondria
both
cardiac
detoxification
thought;
detected
to
types
are
lacking
of glutathione
per-
mitochondria. this
or whether slowly
applied
is clearly
previously
enzyme,
to be seen whether
this
in legend
the mttochondrial
membrane.
present
more
such
and selenium-dependent
matrix,
or mitochondrial
and characterize
than
matrix
over
of
suggest
mitochondrial
are
activity
as described
the enzyme activity
results
selenium-dependent
oxidase
I.
out as previously described (25) Tris HCl, pH 7.4, with 10 mM EDTA proteinwas 11.1 mg/ml. Glut-
results
catalase
the
Table
was determined
the
mitochondrial
within
in the
is
identified
in
pH 8.0.
these
may be more
in the
activity
can be seen,
In conclusion,
previously
as described
was carried used was 1 ti and mitochondrial
shows
mitochondria.
peroxides
ACTIVITY protein)
82.5
mitochondria
Outer
COMMUNICATIONS
than
membrane-bound it
is simply
glutathione dependent
selenium
the
pool
enzyme.
We are currently
further
in
order
to
peroxidase upon a selenium supports
which
attempting answer
this
the
to purify question.
REFERENCES 1.
Myers, Young,
C-E.,
McGuire,
R.C.
(1977)
W-R., Science
Liss,
R.H.,
197:
165-167.
90
Ifrim,
I.,
Grotzinger,
K.,
and
Vol.
96, No.
2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25.
1, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Doroshow, J.H., Locker, G.Y., and Myers, C.E. (1980) J. Clin. Invest. 65: 128-135. Boveris, A., and Chance, B. (1973) Biochem. J. 134: 707-716. Loschen, G., Flohe, L., and Chance, B. (1971) FEBS Lett. 18: 261-264. Boveris, A., Oshino, N., and Chance, B. (1972) Biochem. J. 128: 617-630. Nohl, H., and Hegner, D. (1978) Eur. J. Biochem. 82: 563-567. Flohe, L., Gunzler, W.A., and Ladenstein, R. (1976) In Glutathione: Metabolism and Function, Arias, I.M., and Jakoby, W.B.TEds.), Raven, New York, pp. 115-135. Pryor, W.A. (1973) Federation Proc. 32: 1862-1869. Flohe, L., and Zimmerman, R. (1974) In Glutathione, Flohe, L., Benohr, H.C., Sies, H., Waller, H.D.,and Wended, A., Thieme, Stuttgart, pp. 245259. Hunter, F.E. Jr., Scott, A., Hoffsten, P.E., Guerra, F., Weinstein, J., Schneider, A., Schutz, B., Fink, J., Ford, L., and Smith, E. (1964) J. Biol. Chem. 239: 604-613. Neubert, D., Wojtczak, A.B., and Lehninger, A.L. (1962) Proc. Natl. Acad. Sci. USA 48: 1651-1658. Weisiger, R.A., and Fridovich, I. (1973) J. Biol. Chem. 248: 3582-3592. Nohl, H., and Hegner, D. (1978) FEBS Lett. 89: 126-130. Green, R.C., and O'Brien, P.J. (1970) Biochim. Biophys. Acta 197: 31-39. Sies, H., and Moss, K.M. (1978) Eur. J. Biochem. 84: 377-383. Zakowski, J.J., and Tappel, A.L. (1978) Biochim. Biophys. Acta 526: 65-76. Lawrence, R.A., and Burk, R.F. (1976) Biochem. Biophys. Res. Ccmmun. 71: 952-958. Lowry, o., Rosebrough, N.J., Farr, A.L., and Randall, R.J. (1951) J. Biol. Chem. 193: 265-275. Lawrence, R.A., and Burk, R.F. (1978) J. Nutr. 108: 211-215. Locker, G.Y., Doroshow, J.H., Baldinger, J.C., and Myers, C.E. (1979) Nutr. Rep. Inter. 19: 671-678. Pierce, S., and Tappel, A.L. (1978) Biochim. Biophys. Acta 523: 27-36. Prohaska, J.R., and Ganther, H.E. (1977) Biochem. Biophys. Res. Comm. 76: 437-445. Prohaska, J.R. (1980) Biochim. Biophys. Act. 611: 87-98. Lotscher, H.R., Winterhalter, K.H., Carafoli, E., and Richter, C. (1979) Proc. Natl. Acad. Sci. USA 76: 4340-4344. Pederson, P.L., Greenawalt, J.W., Reynafarje, B., Hullihen, B.J., Decker, G.L., Soper, J.W., and Bustamente, E. (1978) InMethods in Cell Biology, Vol. 20, D.M. Prescott (Ed.), Academic Press7 New York, pp. 411-481.
91
96, No.
September
1, 1980
8lOCHEMlCAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Pages 85-91
16, 1980
MEMBRANE-BOUND GLUTATHIONE Aspandiar
PEROXIDASE-LIKE
G. Ratki*l
ACTIVITY
and Charles
IN MITOCHONDRIA
E. Myers+
*Radiobiology Division, Tufts-New England Medical Center Hospital, 171 Harrison Avenue, Boston, Massachusetts 02111, and +Clinical Pharmacology Branch, National Cancer Institute Bethesda, Maryland 20205 Received
July
21,198O
SUMMARY
A membrane-bound glutathione peroxidase-like activity has been detected in liver and cardiac mitochondrial membrane. This enzyme activity differs from the cytosol and mitochondrial matrix selenium-dependent glutathione peroxidase in that it is membrane bound, sensitive to sonication and tritonX-100, and is unaffected by prolonged feeding of a selenium-free diet. This mitochondrial membrane-bound enzyme activity differs from the glutathione-stransferases which exhibit glutathione peroxidase activity in that it is capable of utilizing both cumene hydroperoxide and hydrogen peroxide as substrates. Digitonin fractionation studies indicate that this enzyme is not located in either inner or outer mitochondrial membrane but rather within inter-membrane space. This newly described membrane-bound enzyme activity may play an important role in the maintenance of cardiac mitochondrial integrity in that mitochondrial matrix does not contain glutathione peroxidase. INTRODUCTION As part
of our
investigation
rubicin
cardiac
toxicity
H202 in
cardiac
mitochondria.
mitochondrial Cardiac
H202/min/mg to result oxidation, for lipid
in
turn, in
peroxidation
of glutathione
and "high
swelling amplitude"
(11).
peroxidation the
and
is
H202 are
to
lipids
function
and has
of liver swelling
Detoxification
of
of
4 (3,4).
0.3-0.6
nmol
and H202 is known (7,8).
mitochondria are
state
produce
of superoxide
of
byproducts
in
membrane
in doxo-
detoxification
greatest
estimated
production
mitochondrial
amplitude"
anion
been
of mitochondrial
peroxidase for
This
of lipid
re-examined
production
have
fact,
affects
"high
we have
their
(3,5,6).
in peroxidation
role
Superoxide
and in
protein
example,
1Requests Institute,
(1,2),
metabolism
mitochondria,
of the
lessened superoxide
been
Lipid
per-
implicated, (9,lO).
by the and
reprints should be addressed to: A. G. Ratki, National Building 10, Room 6N119, Bethesda, Maryland 20205.
Both addition hydrogen Cancer
0006-291X/80/170085-07$01.00/0 85
Copyright 0 1980 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol.
96, No.
peroxide
by mitochondria
Mitochondria (13), are
BIOCHEMICAL
1, 1980
have
and all
has thus
been
shown
to
selenium-dependent
contained
in hepatic
of cardiac
examined,
especially
with
In the present
study,
matrix.
both the
the
described
reported
a glutathione
with
catalase
These
enzymes
Peroxide
detox-
with
activity.
mitochondria
lack
in
some properties
mitochondrial activity
which
glutathione
peroxidase
the selenium-
liver
peroxidase
selenium-dependent
glutathione-S-transferases
(12),
(14-16).
peroxidase
cardiac
space
interest.
have not been as comprehensively
previously
detected
considerable
(12,13-16).
to glutathione
inter-membrane
previously
matrix
COMMUNICATIONS
dismutase
peroxidase
we show that
we have
of
super-oxide
mitochondria
regard
RESEARCH
a subject
contain
peroxidase
Instead,
the mitochondrial
been
mitochondrial
mechanisms
glutathione
BIOPHYSICAL
glutathione
ification
dependent
AND
within
differ
from
peroxidase
and
activity.
METHODS AND MATERIAL CDFl male mice were obtained from Dublin Laboratories, Dublin, VA, and kept on selenium-containing or selenium-free diet as described earlier and liver subcellular fractions and mitochondrial sonication (2). Cardiac and triton-X-100 treatment were done as described in legends to tables. Glutathione peroxidase activity was determined according to Lawrence and Burk (17) with some modifications as described in the legend to Table I. Protein was determined by the method of Lowry et al (18). For most of the glutathione peroxidase assays, physiologic pH was used in order to ensure that the ratio of activities in the various fractions were measured under a reasonable approximation of in vivo conditions. In the digitonin experiments, in order to gain greater sensitivity, the membrane-bound enzyme was assayed at its pH optimum of 8.0. were
RESULTS AND DISCUSSION Of the one,
the
hydrogen
enzymes
known
selenium-dependent peroxide
and
ary
hand,
selenium
cumene
tathione mals results
peroxidase
utilize For
(Table
these
exhibit
as
peroxide
reasons,
animals
substrates
thatmitochondria
to
and are not
utilize
both The
activity,
affected
tissue
on
by diet-
distribution
peroxides are
only
(17,18-21).
peroxidase
in cardiac both
activity,
able
the subcellular
using
86
is
glutathione
I) was measured
mice reveal
peroxidase
peroxidase,
hydrogen
and in selenium-deficient from control
glutathione
hydroperoxide
which
cannot
(23,24).
exhibit glutathione
glutathione-S-transferases the other
to
of glu-
from control as substrates.
the richest
intracellu-
aniThe
Vol.
96, No.
1, 1980
Table
BIOCHEMICAL
I.
AND
BIOPHYSICAL
COMMUNICATIONS
SUBCELLULAR DISTRIBUTION OF GLIJTATHIONE PEROXIDASE ACTIVITY IN HEART MUSCLE WITH DIFFERENT SUBSTRATES IN CONTROL AND SELENIUM-DEFICIENT CDFl MICE CONTROL
Cell
RESEARCH
Hydrogen Peroxide As Substrate (nmoles/min/mg
Fraction
SELENIUM-DEFICIENT Cumene Hydrogen HydroPeroxide Peroxide As As Substrate Substrate (nmoles/min/mg protein)
Cumene HydroPeroxide As Substrate protein)
Homogenate
5.45
7.00
5.78
9.70
Pellet
5.31
6.96
7.51
8.38
Mitochondria
10.30
9.48
Microsome
0
0
1.22
1.86
4.33
5.11
1.28
2.85
Soluble
11.25
10.80
Subcellular fractionation was done by preparing 10% heart homogep ate in 250 mM sucrose, 1 mM Tris, 10 mM EDTA, pH 7.2, in a Brinkmann model PCU-2-110 Polytron 3 times for 5 set at 5.5 settings with cooling in between cycles. After sedimentation of the nuclear fraction (700 x G for 10 min), the supernatant was centrifuged at 10,000 x G for 15 mln to sediment mitochondria. The post-mitochondrial supernatant was centrifuged at 105,000 x G for 60 min to sediment microsomes. Nuclear, mitochondrial, and microsomal pellets were resuspended in the initial buffer. Glutathione peroxidase activity was determined by the decrease in absorbance at 340 w by incubating enzyme in 100 mM Tris, 3 mM EDTA, pH 7.0, 1.2 units glutathione reductase, 0.25 mM GSH, 3.0 mM NaN3, 0.25 mM NADPH, and 0.04 ml4 H202 or 0.075 mM cumene hydroperoxide in 1 ml final volume. Blank reactions with the enzyme source replaced by distilled water were subThe activity is expressed as nmoles NADPH tracted from each assay. oxidized/ min/mg protein using the extinction coefficient for NADPH Succinate-cytochromecreductase activity of 6.22 x lo3 mol-l cm-l. and rotenone-insensitive NADH-cytochrome 2 reductase activity were determined as mitochondrial and microsomal marker enzymes, respectively.
lar
source
twice
that
(Table
I,
tion is
of
glutathione
of the homogenate columns
glutathione less
(Table
than I,
peroxidase
activity
sults
suggest
which
is
more
3 and 4) did
30% of that 1). showed
I,
In
contrast,
a slight
to
with
effect
mitochondrial
peroxidase
effects
87
of
on the
with
selenium
deficiency
soluble
frac-
where
activity
hydrogen
peroxide
glutathione selenium
activity
Selenium
dependent,
mice when assayed
with
a specific
1 and 2).
be selenium
increase
the
heart
expected
of glutathione to
the
columns
the
from control
the presence resistant
have known
peroxidase,
column
cific
(Table
in
peroxidase
deficiency. activity deficiency
spe-
These
re-
in mitochondria than
is
the
Vol.
96, No.
1, 1980
previously
BIOCHEMICAL
described
to utilize
both
Previous
cytosolic cumene
studies
(15,24).
in liver
sonication
(14)
chondrial glutathione the
into
of mitochondria
activity.
selenium-deficient suggest bound
that
but less
Because for
liver
these
we have
X-100
treatment
results
(Table
supernatant.
In contrast,
also
found
selenium-deficient
for
post-sonication
is
free
of glutamembrane
Triton-X-100 complete
treatment loss
of
090%)
of mitochondria
from
These results
enzyme but have
deficiency
so sharply
and
the
matrix
those
with
is
a membranesensitive
to both confirm
to
remains
most
mice.
in the
selenium-deficient
after
sonication Furthermore,
of the matrix
88
activity
the
in the triton-
from
and liver
post-treatment
post-treatment
mice,
However,
is
sonication
in
activity
pellet
both peroxidase
little
enzyme.
reported
and
glutathione in activity
matrix
sonication that
increase
from
previously
of the enzyme activity
by the
control
mice,
most
Our results
release
of this
from
the
reported
in enzyme activity.
mitochondria
B).
in the membrane
of mitochondria
mito-
mitochondrial
that
treatment
by
the
mitochondrial
in nearly
the matrix
where
mitochondria
dependency
disrupt
paralleled
contains
by selenium
liver II
as reflected
liver
lack
contrast
subjected
mitochondria
selenium
which
drop
mitochondria
be liberated
Triton-X-100
(14-16,24)
treatment
of
should
mitochondrial
cardiac
that
existence
so to sonication.
triton-X-100
ernate
it
of
able
substrate.
the
the
of which
A shows
resulted
unaffected
mitochondria
matrix,
mice
mitochondria is
II
enzyme
mice gave a similar
enzyme which
triton-X-100
Table
activity.
cardiac
liver
50% of the enzyme activity.
control
peroxidase
from
behavior
to see if
The pellet,
about
from
the
reason,
a matrix
in
still
as
only
located
both
is
peroxide
reported
liberated
(15,16,24),
enzyme.
possesses
glutathione
been
was assessed
which
peroxidase
fragments,
has
this
mitochondrial
supernatant thione
For
peroxidase
liver
peroxidase
and triton-X-100
membrane.
have
COMMUNICATIONS
but which
hydrogen
mitochondria
enzyme
RESEARCH
peroxidase and
glutathione
This
BIOPHYSICAL
glutathione
hydroperoxide
of a seleniunrdependent matrix
AND
sup-
confirming
the
some enzyme activity and triton-X-100
in
liver is
lost
treatment
mitochondria but
is
29.3%
from of the
Vol.
96, No.
BIOCHEMICAL
1, 1980
Table
II.
AND
EFFECTS OF SONICATION LIVER MITOCHONDRIAL
BIOPHYSICAL
RESEARCH
AND TRITON-X-100 ON CARDIAC AND GLUTATHIONE PEROXIDASE ACTIVITY SONICATION* (nnoles/min/mg
A.
COMMUNICATIONS
TRITON-X-100' protein)
Heart
Intact
mitochondria Post-treatment Post-treatment
Se-deficient intact Post-treatment Post-treatment B.
11.06 0 5.63
supernatant pellet
12.65 0 0.99
mitochondria supernatant pellet
14.41 0.21 2.64
Liver
Intact
mitochondrial Post-treatment Post-treatment
25.45 74.60 24.55
supernatant pellet
Se-deficient intact Post-treatment Post-treatment
25.45 61.15 9.76
mitochondria supernatant pellet
13.99 2.84 4.10
*Mitochondria, 2 to 6 mg/ml protein, were sonicated 10 set x 3 by Branson Sonifier Cell Disruptor 185 with microtip, setting control output on 6 and meter reading 42-44 watts/second, and were sedimented at 105,000 x G for 60 min to separate the mitochondrial membrane pellet, which was resuspended in 250 mM sucrose, 1 mM Tris, 10 mM EDTA, pH 7.2. +To the mitochondrial suspension, 1 to 2 mg/ml, in 250 mM sucrose, 1 mM Tris, 10 mM EDTA, pH 7.2 was added triton-X-100 in 50 mM Tris, 1.5 ml4 EDTA, pH 7.0 to final concentration 0.5% and incubated at 0' for 10 min. The suspension was sedimented at 105,000 x G for 60 min to separate mitochondrial membrane pellet which was resuspended in 250 mM sucrose, 1 mM Tris, 10 mM EDTA, pH 7.2. 110% liver homogenate in 250 mM sucrose, 1 mM Tris, 10 ml4 EDTA, pH 7.2 was centrifuged at 600 x G for 10 min to sediment nuclei. The post-nuclei supernatant was centrifuged at 8,500 x G for 12 min to sediment mitochondria, suspended in 250 mM sucrose, 1 mM Tris, 10 mM EDTA, pH 7.2 to 4-6 mg/ml.
original
mitochondrial
persists.
These
membrane-bound
glutathione
results
consist becane
the
of
treatment contents
the
a standard
the
as
the
localizing
activity
well
as
located outer
membrane
the
previously
the
pellet
possess
a
described
in the matrix.
and
membrane yields
and matrix.
enzyme activity
in
may also
mitochondrial space
89
found
mitochondria
inter-membrane
mitochondrial
one for
liver
peroxidase
disrupts of
inner
that
peroxidase
glutathione
Digitonin releases
suggest
glutathione
selenium-dependent
peroxidase
within
and
mitoplasts This
thus which
technique
the mitochondrial
has
Vol.
96, No.
1, 1980
Table
BIOCHEMICAL
III.
AND
BIOPHYSICAL
RESEARCH
EFFECT OF DIGITONIN TREAlMENT ON CARDIAC GLDTATHIONE PEROXIDASE ACTIVITY
MITOCHONDRIAL
SPECIFIC (nmoles/min/mg Intact
1.59
membrane
Inter-membrane Inner
26.3
space
membrane
1.61
1.89
Matrix
Mitochondria
were
isolated
Digitonin fractionation except that buffer and 250 mM sucro.se, athione peroxidase Table I in Tris-EDTA,
membrane.
Table
III As
inter-membrane
space.
found located
It
remains
truly
pool cytosol
selenium
which
turns
complex
analysis
in
we have
in liver
independent
matrix enzyme
Cardiac while
localized
in
to the
of
addition
to
the
glutathione
peroxidase
a glutathione
peroxidase
mitochondria
both
cardiac
detoxification
thought;
detected
to
types
are
lacking
of glutathione
per-
mitochondria. this
or whether slowly
applied
is clearly
previously
enzyme,
to be seen whether
this
in legend
the mttochondrial
membrane.
present
more
such
and selenium-dependent
matrix,
or mitochondrial
and characterize
than
matrix
over
of
suggest
mitochondrial
are
activity
as described
the enzyme activity
results
selenium-dependent
oxidase
I.
out as previously described (25) Tris HCl, pH 7.4, with 10 mM EDTA proteinwas 11.1 mg/ml. Glut-
results
catalase
the
Table
was determined
the
mitochondrial
within
in the
is
identified
in
pH 8.0.
these
may be more
in the
activity
can be seen,
In conclusion,
previously
as described
was carried used was 1 ti and mitochondrial
shows
mitochondria.
peroxides
ACTIVITY protein)
82.5
mitochondria
Outer
COMMUNICATIONS
than
membrane-bound it
is simply
glutathione dependent
selenium
the
pool
enzyme.
We are currently
further
in
order
to
peroxidase upon a selenium supports
which
attempting answer
this
the
to purify question.
REFERENCES 1.
Myers, Young,
C-E.,
McGuire,
R.C.
(1977)
W-R., Science
Liss,
R.H.,
197:
165-167.
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Ifrim,
I.,
Grotzinger,
K.,
and
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96, No.
2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25.
1, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
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91