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Studies on the immunochemical and functional similarities among iron-sulfur proteins involved in mitochondrial steroid hydroxylations
Vol. 54, No. 2, 1973
STUDIES
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ON THE IMMUNOCHEMICAL AND FUNCTIONAL PROTEINS INVOLVED IN MITOCHONDRIAL Jeffrey The The
Received
Toxicology University
August
Center, of
SIMILARITIES AMONG STEROID HYDROXYLATIONS
IRON-SULFUR
Baron
The Department Iowa, Iowa City,
of Pharmacology, Iowa 52242
7, 1973
SUMMARY : The effects of a goat anti-adrenodoxin immunoglobulin fraction on the NADPHand NADH-dependent electron transport sequences in the mitochondria of steroidogenic tissues have been examined. The NADPH-cytochrome c reductase activities of sonicated mitochondrial preparations derived from bovTne adrenal cortex and rat adrenals and ovaries were inhibited in a similar manner in the presence of this antibody, while the inhibition of this activity in rat testicular mitochondrial preparations was less pronounced. The NADH-dependent reduction of cytochrome c catalyzed by these mitochondrial preparations was not affected by the antibody. These results indicate that, while they may not be identical, the iron-sulfur proteins involved in mammalian mitochondrial steroid hydroxylations exhibit immunochemical and functional similarities. The lone
oxidative
is
the
initial
adrenal,
testis,
reaction
are
require
NADPH
chain
cleavage
ovary
and
:
IlB-hydroxylase been
resolved
into
cholesterol been sulfur of
In Omura
the
intermediate cytochrome
which
(5)
between P-450.
demonstrated
the
both
cytochrome
of
deoxycorticosterone
0 1973 by Academic
by
of
system that
P-450
of
studies
and
cytochrome
for
catalyzed
Press, Inc.
bovine
of
be
human
com-
the
adrenals, to
which
(5).
has
Although
do the
and
similar
has
contain
the also
the
mitochondria
an
lib-hydroxylase
adrenocortical functions
flavoprotein
recent
requirement
(3)
not ironsystem
(6).
adrenodoxin
reduced
More
in
side-
protein
case to
mitochondria
adrenodoxin
and
NADPH-flavoprotein the
al.
tissues
ovarian
mitochondria et
the this
these
three
appear
testicular
these
replace
the
in
thus
Omura
system
mitochondria
proposed
which,
adrenocortical
components, can
an
in
cholesterol
rat into
oxidase;
systems
components
The
(2),
pregneno-
catalyzing in
(1).
resolved
protein
bovine
IIB-hydroxylase al .
of
Copyright
its
been
terminal
cleavage
adrenocortical
et
the
of
systems
activity
form
hormones
fraction
adrenocortical each
These
three
into
protein bovine
bovine
iron-sulfur
side-chain
resolved
for
to
steroid
enzyme
mitochondrial
have
system
of
The
the
adrenodoxin.
side-chain
biosynthesis
oxygen
of
an
cholesterol
placenta.
P-450,
and named
the
molecular
cytochrome
been
the
with
mitochondria
dehydrogenase; has
in and
systems
(4)
ponents
step
associated
cleavage
placental
of
an
dehydrogenase employing
adrenodoxin
by
mitochondria, as
in c
bovine 764
an
as
well
the
electron and
antibody
to
transfer oxidized adrenodoxin
NADPH-dependent as
adrenocortical
in
the
reductions
llB-hydroxylation mitochondria
(7).
BIOCHEMICAL
Vol. 54, No. 2, 1973
I
, mg
Figure
1:
Titration adrenocortical
of
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
/ IO
05 protem/mg
Ig
I 15
/ 20
mitochondrv3
NADPH-cytochrome mitochondria
2
protein
reductase activity goat anti-adrenodoxin
by
of
bovine immunoglubulin.
Bovine adrenocortical mitochondria were sonicated for 4 minutes in 0.5minute intervals. Each 2.2-ml reaction mixture contained 36.4 uM cytochrome c, 0.91 mM KCN, 0.1 mg of mitochondrial protein and 50 mM Tris-chloride buffer, pH 7.4. The reactions were initiated by the addition of 50 PM NADPH. Anti-adrenodoxin and preimmune immunoglobulin (lg) were substituted for buffer in the indicated concentrations. The solid line represents the activities in the presence of anti-adrenodoxin immunoglobulin, and the dashed line represents activities in the presence of preimmune immunoglobul in. In the absence of imnunoglobulin, NADPH-cytochrome 2 reductase activity was 60.7 nmoles cytochrome protein. -c reduced/min/mg
It
is
generally
tissues
assumed
function
cholesterol
in
that
the
examine
the
proteins
of
iron-sulfur
a comparable
catalyzed
summarizes
the
by
initial
manner
the
immunochemica
an
functional
an and
the of
employing
1 and ovar
in
mitochondria
results
adrenal,
proteins
in
side-chain
steroidogenic
cleavage
these
tissues.
antibody
to
similarities
testicular
other
of
This
communication
adrenodoxin among
to
the
iron-sulfur
mi tochondria.
METHODS Bovine of 160 For of were
and
rats,
studies human
mitochondria
(8).
Boyd
g Holtzman
and
employing
hours
immunoglobulin
serum,
respectively,
determined
by
cytochrome
5
the
the
ovaries
biuret
reductases
were
mitochondria,
after
the
fractions
were
injection.
were
prepared
(9).
determined
testes
were by rats
sulfate The as
765
The
previously
from
same
48
method 140-
method.
500
units
hours
and
anti-adrenodoxin immune
fractionation. activities
the
removed the
every
from
to
received
subcutaneously
last
ammonium
reaction
according
prepared male
(Squibb)
by
prepared and
mitochondria
gonadotropin 24
were
Adrenals,
testicular
chorionic
sacrificed
preimmune goat
adrenocortica
Simpson
and
and preimnune
Protein of
NADPH-
described
and (7)
was NADHafter
Vol. 54, No. 2, 1973
BIOCHEMICAL
I
I
0.5 mg
Figure
Ig
2:
The
I
1
I
15
IO
protem/mg
mlfochondriol
Titration mitochondria
of
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
20
615’ mg
protean
NADPH-cytochrome 4 by goat anti-adrenodoxin
absence nmoles
conditions were the same as those of immunoglobulin, NADPH-cytochrome cytochrome 4. reduced/min/mg protein.
Figure
3: The
absence nmoles
the
~185
RESULTS
had
AND
The
from
of
of
bovine to the
-c
activity
was
Unlike
its
data
in
previous
y-globulin
a goat
with
for
a total
of (20
of
for
adrenal
1. In the was 90.0
of
rat n.
Figure activity
4 minutes
protein
rat
Figure activity
activity irnnunoglobuli
described 4 reductase
55 watts
1
In
using
the
64.1
was
a Branson
kc).
inhibitory
4 not
fraction
these
presence on
the
reductase
require studies
the
effect that
in
derived
Baron
be
inhibition
(7)
4 without
immune
in rabbit
766
production Figure to
of
preimmune
These
and
the
of
I,
the
sonicated NADPH-
No diminution
reductase effect
the
serum
are an
in
this
fraction.
activity, on
mitochondria, results
which
of
irnnunoglobulin
adrenocortical (5).
from
the
was
al.
in
fraction
NADPH-cytochrome
bovine
et
an
the
seen
mitochondria.
of
antibody
adrenodoxin of
can
produced of
isolated
elicits
As
immunoglobulin
activity in
adrenodoxin
mitochondria protein.
mitochondria
reductase
I show
homogeneous
anti-adrenodoxin
observed
Table
does
of
iron-sulfur
goat
NADH-cytochrome which
for
output
adrenocortical
the
adrenocortical
cytochrome
sonicated
an
m~tochandr~ol
DISCUSSION
antibody
addition
the
been at
immunization
purified
bovine
of NADPH-cytochrome 2 reductase mitochondria by anti-adrenodoxin
Sonifier
proteln/mg
activity immunoglobulin.
described c reductase -
conditions were the same as those of immunoglobulin, NADPH-cytochrome cytochrome protein. -c reduced/min/mg
mitochondria
model
an
Titration ovarian
reductase
Ig
the activity an
of activity
agreement
with
anti-adrenodoxin was
employed.
It
was
BIOCHEMICAL
Vol. 54, No. 2, 1973
Table
1.
adrenal
0 2.0
(immune)
2.0 adrenal
Rat
a The conditions except that NADH.
however,
inhibitory
that
to
protein
inhibit
of can
that
the
electron
seen
58.6
100
2.0
immune)
58.9
101
2.0
preimmune)
58.6
100
95.5
100
2.5
( immune)
95.8
100
2.5
(preimmune)
95.4
100
imnunoglobulin
goat
the
Table in
the
data
in presented
and in
results bovine Figure
was
presence
of
inhibition
strikingly
with
in
mitochondrial two
of
equal
found rat
to adrenal
bovine
the
and
antibody
‘767
that,
analogous
as
the demonstrate
NADPH-dependent exhibit the
immunochemical
functional
similarity
adrenals. 3 show
adrenoactivity
differs,
species
indicate
more
reductase
similar
these further
an
also
c
l-4, 90 pM
times
by
obtained
the
extent
involved of
was
catalyzed
results
2 are
5-10
than
NADH-cytochrome in
the
adrenals
these rat
the
observed
1 and
was
activity
activity
of
Although
proteins
Moreover,
“adrenodoxin”
was
1.
in
to
inhibition
for Figures addition of
fraction
reductase
Similar
Figures
iron-sulfur
fraction
-c reductase rabbit y-globulin.
c
mitochondria in
described by the
immunoglobulin
no
transport
The
96
2).
curves
similarity. of
56.6
NADPH-cytochrome
adrenal
be
preinnnune)
of
(Figure
titration
2.0
the
mitochondria,
rat
100
anti-adrenodoxin
mitochondria cortical
100
58.8
NADPH-cytochrome
goat the
59.0
107
immune)
same as those were initiated
concentration The
101
2.0
were the reactions
the
Percent of control activity
369.4 348.7
0
(lg)
c
100
0
testis
found,
(preimmune)
innnunoglobulin of the mito-
346.8
0
ovary
Rat
nmoles cyt reduced/minT mg protein
lg protein/mg mitochondrial protein
Tissue
Rat
RESEARCH COMMUNICATIONS
Lack of effect of goat anti-adrenodoxin on NADH-cytochrome c reductase activities chondria of steroidggenic tissues.a
mg
Bovine cortex
AND BIOPHYSICAL
to
the
results
Vol. 54, No. 2, 1973
BIOCHEMICAL
Figure
NADPH-cytochrome mitochondria
4:
Titration of rat testicular
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
c reductase by-anti-adrenodoxin
activity
of HCG-treated immunoglobul in.
The conditions were the same as those described for Figure that 0.5 mg of mitochondrial protein was present in each reaction In the absence of immunoglobulin, NADPH-cytochrome c reductase 5.0 nmoles cytochrome 4 reduced/min/mg protein.
obtained
with
rat
immunoglobulin
almost 2).
cytochrome
4
rat
the -et
untreated
-*al
(IO) contain
rats
with
of
increased
synthesis
observations, from
consistently However, were
studied, of
curve
an
testes
of the
mitochondria
of
protein.
from
In
reductase
activity
was
reductase
activity
in
NADH-dependent (Table
with
rat
reduction I).
testicular
It
is
observed of
readily
mitochondria
768
cytochrome apparent (Figure
the
with
these
and
was
not
fraction.
rats
-c
in
mitochondria low
of
protein,
results
extremely
testes
was
functionally
mitochondria
of
-c
fraction
protein
immunoglobulin the
NADH-
agreement
activity
anti-adrenodoxin
alter
iron-sulfur
NADPH-cytochrome
the
not
(HCG)
was
titration
testicular
gonadotropin
rats
this
and
although
reductase
NADPH-
mitochondria
no adrenodoxin-like
-c
of
iron-sulfur
mitochondria.
iron-sulfur
derived
the
NADPH-cytochrome
conditions
obtained
did
adrenal
untreated
immunoglobulin
inhibition same
such
antibody Thus,
that,
or
adrenal
immunochemically
chorionic
the
anti-adrenodoxin
the
in
rat
be
reported
NADPH-cytochrome
by
I). to
little
the
inhibited when
inhibition
(Table
human
of
the
appears
have
activity Indeed,
with
except mixture. activity was
anti-adrenodoxin
the
mitochondria. obtained
protein
the
inhibiting
ovarian that
activity
rats
of
mitochondria,
comparable
treatment
prepared
rat to
adrenal
reductase
mitochondria,
capable
mitochondria
to Mason
of
in
ovarian
similar
of
identical As
adrenal
was
-c reductase is
(Figure
of
bovine
fraction
cytochrome curve
and
I,
treated
with
elevated the
and
presence
(Figure
HCG
of
4).
-c was that
the
4)
differs
the
No
found
under
titration greatly
BIOCHEMICAL
Vol. 54, No. 2, 1973
from
those
for
observations
adrenal may
testicular
iron-sulfur
similarity
with
be more of may be
the
the
large
in
protein This
inability
of
reductase
activity
inhibit
of
to
these
mi tochondria
greater
detail
iron-sulfur
the
(7). the
of
may
inhibit
involved mammalian
(b)
a portion
(c)
the
iron-sulfur
protein
ovary, with
embedded most
the
relatively
of
the
the
NADPH-cytochrome
will
testis
mitochondrial
the
for
the 5
mitochondria system
while
solubilized
undoubtedly
in
among occurring
it from
define
similarities
hydroxylations
steroidogenic
comparison
the
thus
explanation
functional
steroid
in
and all in
may
membrane
likely
reductase
studies and
in
antibody;
adrenocortical of
thus
mitochondria
react
be the
bovine
Additional
might
testicular
completely
activity
and
rat
and
to
is
immunochemical
proteins
mitochondria
be able
sonicated
proteins
of
adrenal
which
the
the
immunochemical
mitochondrial
the
possibility
completely
or
testicular
not
molecules
antibody
of
activity
of
may
latter
the
effects
the
These (a)
minimal
iron-sulfur
protein;
l-3).
possibilities: only
ovarian
RESEARCH COMMUNICATIONS
(Figures
following
exhibit
reductase
proteins molecule
iron-sulfur membrane.
may
iron-sulfur
situated
the
inhibitory -c
iron-sulfur
antibody
mitochondria of
and
the
the
differently
with
one
adrenal to
involve
ovarian
to
NADPH-cytochrome
not
can
due
protein
resistent
the
and
be
AND BIOPHYSICAL
the
in
the
tissues.
ACKNOWLEDGEMENTS The
author
throughout Public
these Health
thanks
Mrs.
studies. Service
Cathy This
Grant
Hayford research
for was
her
expert
supported
technical in
part
assistence by
U.S.
GM 12675.
REFERENCES
I. 2.
1:
5. 6. 7. a. 9. 0.
Sulimovici, S.I. and Boyd, G.S., Vitam. Horm. (New York), g, 199 (1969). Simpson, E.R. and Boyd, G.S., Biochem.Biophys. Res. Commun., 8, 945 (1967). Sulimovici, S. and Boyd, G.S., Steroids, 12, 127 (1968). Mason, J.I. and Boyd, G.S., Eur. J. Biochem., 21 308 (1971). Omura, T., Sanders, E., Estabrook, R.W., Cooper, D.Y. and Rosenthal, O., Arch. Biochem. Biophys., 117, 660 (1966). Kimura, T. and Ohno, H., J. Biochem. 63, 716 (1968). Baron, J., Taylor, W.E. and Masters, B.S.S., Arch. Biochem. Biophys., 150, 105 (1972). Simpson, E.R. and Boyd, G.S., Eur. J. Biochem., 2, 489 (1971). Gornall, A.G., Bardawill, C.J. and David, M.M., J. Biol. Chem., 177, 751 Mason, J.I., Estabrook, R.W. and Purvis, J.L., Ann. N.Y. Acad. ST.,
-212 (1973).
769
STUDIES
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ON THE IMMUNOCHEMICAL AND FUNCTIONAL PROTEINS INVOLVED IN MITOCHONDRIAL Jeffrey The The
Received
Toxicology University
August
Center, of
SIMILARITIES AMONG STEROID HYDROXYLATIONS
IRON-SULFUR
Baron
The Department Iowa, Iowa City,
of Pharmacology, Iowa 52242
7, 1973
SUMMARY : The effects of a goat anti-adrenodoxin immunoglobulin fraction on the NADPHand NADH-dependent electron transport sequences in the mitochondria of steroidogenic tissues have been examined. The NADPH-cytochrome c reductase activities of sonicated mitochondrial preparations derived from bovTne adrenal cortex and rat adrenals and ovaries were inhibited in a similar manner in the presence of this antibody, while the inhibition of this activity in rat testicular mitochondrial preparations was less pronounced. The NADH-dependent reduction of cytochrome c catalyzed by these mitochondrial preparations was not affected by the antibody. These results indicate that, while they may not be identical, the iron-sulfur proteins involved in mammalian mitochondrial steroid hydroxylations exhibit immunochemical and functional similarities. The lone
oxidative
is
the
initial
adrenal,
testis,
reaction
are
require
NADPH
chain
cleavage
ovary
and
:
IlB-hydroxylase been
resolved
into
cholesterol been sulfur of
In Omura
the
intermediate cytochrome
which
(5)
between P-450.
demonstrated
the
both
cytochrome
of
deoxycorticosterone
0 1973 by Academic
by
of
system that
P-450
of
studies
and
cytochrome
for
catalyzed
Press, Inc.
bovine
of
be
human
com-
the
adrenals, to
which
(5).
has
Although
do the
and
similar
has
contain
the also
the
mitochondria
an
lib-hydroxylase
adrenocortical functions
flavoprotein
recent
requirement
(3)
not ironsystem
(6).
adrenodoxin
reduced
More
in
side-
protein
case to
mitochondria
adrenodoxin
and
NADPH-flavoprotein the
al.
tissues
ovarian
mitochondria et
the this
these
three
appear
testicular
these
replace
the
in
thus
Omura
system
mitochondria
proposed
which,
adrenocortical
components, can
an
in
cholesterol
rat into
oxidase;
systems
components
The
(2),
pregneno-
catalyzing in
(1).
resolved
protein
bovine
IIB-hydroxylase al .
of
Copyright
its
been
terminal
cleavage
adrenocortical
et
the
of
systems
activity
form
hormones
fraction
adrenocortical each
These
three
into
protein bovine
bovine
iron-sulfur
side-chain
resolved
for
to
steroid
enzyme
mitochondrial
have
system
of
The
the
adrenodoxin.
side-chain
biosynthesis
oxygen
of
an
cholesterol
placenta.
P-450,
and named
the
molecular
cytochrome
been
the
with
mitochondria
dehydrogenase; has
in and
systems
(4)
ponents
step
associated
cleavage
placental
of
an
dehydrogenase employing
adrenodoxin
by
mitochondria, as
in c
bovine 764
an
as
well
the
electron and
antibody
to
transfer oxidized adrenodoxin
NADPH-dependent as
adrenocortical
in
the
reductions
llB-hydroxylation mitochondria
(7).
BIOCHEMICAL
Vol. 54, No. 2, 1973
I
, mg
Figure
1:
Titration adrenocortical
of
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
/ IO
05 protem/mg
Ig
I 15
/ 20
mitochondrv3
NADPH-cytochrome mitochondria
2
protein
reductase activity goat anti-adrenodoxin
by
of
bovine immunoglubulin.
Bovine adrenocortical mitochondria were sonicated for 4 minutes in 0.5minute intervals. Each 2.2-ml reaction mixture contained 36.4 uM cytochrome c, 0.91 mM KCN, 0.1 mg of mitochondrial protein and 50 mM Tris-chloride buffer, pH 7.4. The reactions were initiated by the addition of 50 PM NADPH. Anti-adrenodoxin and preimmune immunoglobulin (lg) were substituted for buffer in the indicated concentrations. The solid line represents the activities in the presence of anti-adrenodoxin immunoglobulin, and the dashed line represents activities in the presence of preimmune immunoglobul in. In the absence of imnunoglobulin, NADPH-cytochrome 2 reductase activity was 60.7 nmoles cytochrome protein. -c reduced/min/mg
It
is
generally
tissues
assumed
function
cholesterol
in
that
the
examine
the
proteins
of
iron-sulfur
a comparable
catalyzed
summarizes
the
by
initial
manner
the
immunochemica
an
functional
an and
the of
employing
1 and ovar
in
mitochondria
results
adrenal,
proteins
in
side-chain
steroidogenic
cleavage
these
tissues.
antibody
to
similarities
testicular
other
of
This
communication
adrenodoxin among
to
the
iron-sulfur
mi tochondria.
METHODS Bovine of 160 For of were
and
rats,
studies human
mitochondria
(8).
Boyd
g Holtzman
and
employing
hours
immunoglobulin
serum,
respectively,
determined
by
cytochrome
5
the
the
ovaries
biuret
reductases
were
mitochondria,
after
the
fractions
were
injection.
were
prepared
(9).
determined
testes
were by rats
sulfate The as
765
The
previously
from
same
48
method 140-
method.
500
units
hours
and
anti-adrenodoxin immune
fractionation. activities
the
removed the
every
from
to
received
subcutaneously
last
ammonium
reaction
according
prepared male
(Squibb)
by
prepared and
mitochondria
gonadotropin 24
were
Adrenals,
testicular
chorionic
sacrificed
preimmune goat
adrenocortica
Simpson
and
and preimnune
Protein of
NADPH-
described
and (7)
was NADHafter
Vol. 54, No. 2, 1973
BIOCHEMICAL
I
I
0.5 mg
Figure
Ig
2:
The
I
1
I
15
IO
protem/mg
mlfochondriol
Titration mitochondria
of
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
20
615’ mg
protean
NADPH-cytochrome 4 by goat anti-adrenodoxin
absence nmoles
conditions were the same as those of immunoglobulin, NADPH-cytochrome cytochrome 4. reduced/min/mg protein.
Figure
3: The
absence nmoles
the
~185
RESULTS
had
AND
The
from
of
of
bovine to the
-c
activity
was
Unlike
its
data
in
previous
y-globulin
a goat
with
for
a total
of (20
of
for
adrenal
1. In the was 90.0
of
rat n.
Figure activity
4 minutes
protein
rat
Figure activity
activity irnnunoglobuli
described 4 reductase
55 watts
1
In
using
the
64.1
was
a Branson
kc).
inhibitory
4 not
fraction
these
presence on
the
reductase
require studies
the
effect that
in
derived
Baron
be
inhibition
(7)
4 without
immune
in rabbit
766
production Figure to
of
preimmune
These
and
the
of
I,
the
sonicated NADPH-
No diminution
reductase effect
the
serum
are an
in
this
fraction.
activity, on
mitochondria, results
which
of
irnnunoglobulin
adrenocortical (5).
from
the
was
al.
in
fraction
NADPH-cytochrome
bovine
et
an
the
seen
mitochondria.
of
antibody
adrenodoxin of
can
produced of
isolated
elicits
As
immunoglobulin
activity in
adrenodoxin
mitochondria protein.
mitochondria
reductase
I show
homogeneous
anti-adrenodoxin
observed
Table
does
of
iron-sulfur
goat
NADH-cytochrome which
for
output
adrenocortical
the
adrenocortical
cytochrome
sonicated
an
m~tochandr~ol
DISCUSSION
antibody
addition
the
been at
immunization
purified
bovine
of NADPH-cytochrome 2 reductase mitochondria by anti-adrenodoxin
Sonifier
proteln/mg
activity immunoglobulin.
described c reductase -
conditions were the same as those of immunoglobulin, NADPH-cytochrome cytochrome protein. -c reduced/min/mg
mitochondria
model
an
Titration ovarian
reductase
Ig
the activity an
of activity
agreement
with
anti-adrenodoxin was
employed.
It
was
BIOCHEMICAL
Vol. 54, No. 2, 1973
Table
1.
adrenal
0 2.0
(immune)
2.0 adrenal
Rat
a The conditions except that NADH.
however,
inhibitory
that
to
protein
inhibit
of can
that
the
electron
seen
58.6
100
2.0
immune)
58.9
101
2.0
preimmune)
58.6
100
95.5
100
2.5
( immune)
95.8
100
2.5
(preimmune)
95.4
100
imnunoglobulin
goat
the
Table in
the
data
in presented
and in
results bovine Figure
was
presence
of
inhibition
strikingly
with
in
mitochondrial two
of
equal
found rat
to adrenal
bovine
the
and
antibody
‘767
that,
analogous
as
the demonstrate
NADPH-dependent exhibit the
immunochemical
functional
similarity
adrenals. 3 show
adrenoactivity
differs,
species
indicate
more
reductase
similar
these further
an
also
c
l-4, 90 pM
times
by
obtained
the
extent
involved of
was
catalyzed
results
2 are
5-10
than
NADH-cytochrome in
the
adrenals
these rat
the
observed
1 and
was
activity
activity
of
Although
proteins
Moreover,
“adrenodoxin”
was
1.
in
to
inhibition
for Figures addition of
fraction
reductase
Similar
Figures
iron-sulfur
fraction
-c reductase rabbit y-globulin.
c
mitochondria in
described by the
immunoglobulin
no
transport
The
96
2).
curves
similarity. of
56.6
NADPH-cytochrome
adrenal
be
preinnnune)
of
(Figure
titration
2.0
the
mitochondria,
rat
100
anti-adrenodoxin
mitochondria cortical
100
58.8
NADPH-cytochrome
goat the
59.0
107
immune)
same as those were initiated
concentration The
101
2.0
were the reactions
the
Percent of control activity
369.4 348.7
0
(lg)
c
100
0
testis
found,
(preimmune)
innnunoglobulin of the mito-
346.8
0
ovary
Rat
nmoles cyt reduced/minT mg protein
lg protein/mg mitochondrial protein
Tissue
Rat
RESEARCH COMMUNICATIONS
Lack of effect of goat anti-adrenodoxin on NADH-cytochrome c reductase activities chondria of steroidggenic tissues.a
mg
Bovine cortex
AND BIOPHYSICAL
to
the
results
Vol. 54, No. 2, 1973
BIOCHEMICAL
Figure
NADPH-cytochrome mitochondria
4:
Titration of rat testicular
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
c reductase by-anti-adrenodoxin
activity
of HCG-treated immunoglobul in.
The conditions were the same as those described for Figure that 0.5 mg of mitochondrial protein was present in each reaction In the absence of immunoglobulin, NADPH-cytochrome c reductase 5.0 nmoles cytochrome 4 reduced/min/mg protein.
obtained
with
rat
immunoglobulin
almost 2).
cytochrome
4
rat
the -et
untreated
-*al
(IO) contain
rats
with
of
increased
synthesis
observations, from
consistently However, were
studied, of
curve
an
testes
of the
mitochondria
of
protein.
from
In
reductase
activity
was
reductase
activity
in
NADH-dependent (Table
with
rat
reduction I).
testicular
It
is
observed of
readily
mitochondria
768
cytochrome apparent (Figure
the
with
these
and
was
not
fraction.
rats
-c
in
mitochondria low
of
protein,
results
extremely
testes
was
functionally
mitochondria
of
-c
fraction
protein
immunoglobulin the
NADH-
agreement
activity
anti-adrenodoxin
alter
iron-sulfur
NADPH-cytochrome
the
not
(HCG)
was
titration
testicular
gonadotropin
rats
this
and
although
reductase
NADPH-
mitochondria
no adrenodoxin-like
-c
of
iron-sulfur
mitochondria.
iron-sulfur
derived
the
NADPH-cytochrome
conditions
obtained
did
adrenal
untreated
immunoglobulin
inhibition same
such
antibody Thus,
that,
or
adrenal
immunochemically
chorionic
the
anti-adrenodoxin
the
in
rat
be
reported
NADPH-cytochrome
by
I). to
little
the
inhibited when
inhibition
(Table
human
of
the
appears
have
activity Indeed,
with
except mixture. activity was
anti-adrenodoxin
the
mitochondria. obtained
protein
the
inhibiting
ovarian that
activity
rats
of
mitochondria,
comparable
treatment
prepared
rat to
adrenal
reductase
mitochondria,
capable
mitochondria
to Mason
of
in
ovarian
similar
of
identical As
adrenal
was
-c reductase is
(Figure
of
bovine
fraction
cytochrome curve
and
I,
treated
with
elevated the
and
presence
(Figure
HCG
of
4).
-c was that
the
4)
differs
the
No
found
under
titration greatly
BIOCHEMICAL
Vol. 54, No. 2, 1973
from
those
for
observations
adrenal may
testicular
iron-sulfur
similarity
with
be more of may be
the
the
large
in
protein This
inability
of
reductase
activity
inhibit
of
to
these
mi tochondria
greater
detail
iron-sulfur
the
(7). the
of
may
inhibit
involved mammalian
(b)
a portion
(c)
the
iron-sulfur
protein
ovary, with
embedded most
the
relatively
of
the
the
NADPH-cytochrome
will
testis
mitochondrial
the
for
the 5
mitochondria system
while
solubilized
undoubtedly
in
among occurring
it from
define
similarities
hydroxylations
steroidogenic
comparison
the
thus
explanation
functional
steroid
in
and all in
may
membrane
likely
reductase
studies and
in
antibody;
adrenocortical of
thus
mitochondria
react
be the
bovine
Additional
might
testicular
completely
activity
and
rat
and
to
is
immunochemical
proteins
mitochondria
be able
sonicated
proteins
of
adrenal
which
the
the
immunochemical
mitochondrial
the
possibility
completely
or
testicular
not
molecules
antibody
of
activity
of
may
latter
the
effects
the
These (a)
minimal
iron-sulfur
protein;
l-3).
possibilities: only
ovarian
RESEARCH COMMUNICATIONS
(Figures
following
exhibit
reductase
proteins molecule
iron-sulfur membrane.
may
iron-sulfur
situated
the
inhibitory -c
iron-sulfur
antibody
mitochondria of
and
the
the
differently
with
one
adrenal to
involve
ovarian
to
NADPH-cytochrome
not
can
due
protein
resistent
the
and
be
AND BIOPHYSICAL
the
in
the
tissues.
ACKNOWLEDGEMENTS The
author
throughout Public
these Health
thanks
Mrs.
studies. Service
Cathy This
Grant
Hayford research
for was
her
expert
supported
technical in
part
assistence by
U.S.
GM 12675.
REFERENCES
I. 2.
1:
5. 6. 7. a. 9. 0.
Sulimovici, S.I. and Boyd, G.S., Vitam. Horm. (New York), g, 199 (1969). Simpson, E.R. and Boyd, G.S., Biochem.Biophys. Res. Commun., 8, 945 (1967). Sulimovici, S. and Boyd, G.S., Steroids, 12, 127 (1968). Mason, J.I. and Boyd, G.S., Eur. J. Biochem., 21 308 (1971). Omura, T., Sanders, E., Estabrook, R.W., Cooper, D.Y. and Rosenthal, O., Arch. Biochem. Biophys., 117, 660 (1966). Kimura, T. and Ohno, H., J. Biochem. 63, 716 (1968). Baron, J., Taylor, W.E. and Masters, B.S.S., Arch. Biochem. Biophys., 150, 105 (1972). Simpson, E.R. and Boyd, G.S., Eur. J. Biochem., 2, 489 (1971). Gornall, A.G., Bardawill, C.J. and David, M.M., J. Biol. Chem., 177, 751 Mason, J.I., Estabrook, R.W. and Purvis, J.L., Ann. N.Y. Acad. ST.,
-212 (1973).
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