Originally published In Press as doi:10.1074/jbc.M004431200 on July 27, 2000
J. Biol. Chem., Vol. 275, Issue 44, 34415-34423, November 3, 2000
Accumulation of Mitochondrial P450MT2, NH2-terminal
Truncated Cytochrome P4501A1 in Rat Brain during Chronic Treatment
with 
-Naphthoflavone
A ROLE IN THE METABOLISM OF NEUROACTIVE DRUGS*
Ettickan
Boopathi,
Hindupur K.
Anandatheerthavarada
,
Shripad V.
Bhagwat§,
Gopa
Biswas,
Ji-Kang
Fang, and
Narayan G.
Avadhani¶
From the Department of Animal Biology and Mari Lowe Center for
Comparative Oncology, School of Veterinary Medicine, University of
Pennsylvania, Philadelphia, Pennsylvania 19104-6047
Received for publication, May 23, 2000, and in revised form, July 13, 2000
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ABSTRACT |
The biochemical and molecular characteristics of
cytochrome P4501A1 targeted to rat brain mitochondria was studied to
determine the generality of the targeting mechanism previously
described for mitochondrial cytochrome P450MT2 (P450MT2) from rat
liver. In rat brain and C6 glioma cells chronically exposed to
-naphoflavone (BNF), P450MT2 content reached 50 and 95% of the
total cellular pool, respectively. P450MT2 from 10 days of BNF-treated
rat brain was purified to over 85% purity using hydrophobic
chromatography followed by adrenodoxin affinity binding. Purified brain
P450MT2 consisted of two distinct molecular species with
NH2 termini identical to liver mitochondrial forms.
These results confirm the specificity of endoprotease-processing sites.
The purified P450MT2 showed a preference for adrenodoxin + adrenodoxin
reductase electron donor system and exhibited high erythromycin
N-demethylation activity. Brain mitoplasts from 10-day
BNF-treated rats and also purified P450MT2 exhibited high
N-demethylation activities for a number of neuroactive
drugs, including trycyclic anti-depressants, anti-convulsants, and
opiates. At 10 days of BNF treatment, the mitochondrial metabolism of
these neuroactive drugs represented about 85% of the total tissue
activity. These results provide new insights on the role of P450MT2 in
modulating the pharmacological potencies of different neuroactive drugs
in chronically exposed individuals.
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INTRODUCTION |
Cytochrome P450 (P450)1
enzymes play a critical role in the metabolism of an array of
endogenous as well as exogenous substrates (1-3). The xenobiotic
inducible forms with roles in the metabolism of carcinogens,
pollutants, and drugs were thought to be exclusively associated with
the endoplasmic reticulum (hereafter referred to as microsomes) of
liver, brain, and other tissues. In contrast to this general belief,
recent reports from our laboratory showed that the BNF-inducible
P4501A1 and phenobarbital-inducible P4502B1 are also targeted to
mitochondria under both in vitro and in vivo cell
transfection conditions. These results are consistent with previous
studies from our, as well as, other laboratories showing the presence
of P450 proteins cross-reacting with antibodies to the major microsomal
forms, in liver and brain mitochondria from inducer treated and
untreated rats, and also insects (4-10). Direct sequencing of hepatic
mitochondrial P450 proteins purified from BNF-treated rats suggested
the occurrence of two forms of P450MT2, both of which were
NH2-terminal cleaved versions of P4501A1 (11). The
molecular form cleaved past the 4th amino acid residue (+5/1A1) represents a minor component while that cleaved past residue 32 (+33/1A1) represents the major component in mitochondria from BNF-treated rat liver. This major form will be routinely referred to as
P450MT2 throughout this paper.
The mitochondrial targeted P450MT2 exhibited many molecular and
biochemical properties distinct from the parent microsomal P4501A1
(12): 1) P450MT2 interacted with Adx with an affinity of 0.6 µM Kd, 2) functionally
productive interaction of Adx with P450MT2 occurred through the same
COOH-terminal basic domain and the same positively charged residues
that are known to be involved in interaction with bona fide
mitochondrial P450s, such as P450scc and P450c27 (13, 14), 3) P450MT2
bound to erythromycin (Kd of 50 µM) as determined by spectral analysis, and 4) P450MT2
exhibited high ERND activity, but vastly reduced CYP1A1 specific
marker, EROD activity, in an Adx supported system. In contrast, the
microsomal P4501A1 with intact NH2-terminal end showed very
low ERND, but high EROD activity, in a P450 reductase-supported system.
The ERND activity of the mitochondrial targeted P4501A1 was further supported by experiments showing that mitochondrial P450MT2 rendered protection against erythromycin mediated inhibition of mitochondrial translation (15). Thus, the NH2-terminal truncated
mitochondrial P450MT2 may be conformationally different from the
microsomal P4501A1.
We hypothesized that the NH2-terminal signals of a number
of microsomal P450s, including 1A1, are chimeric in that they carry signals for targeting proteins to both the endoplasmic reticulum and mitochondria. The chimeric nature of the amino-terminal 45-amino acid stretch of P4501A1 was further supported by the ability of this
signal to target heterologous proteins such as the cytosolic dihydrofolate reductase and mature portion of rat P450c27 to
endoplasmic reticulum and mitochondria (16). Our studies on the
mechanism of mitochondrial targeting of P4501A1 suggested the
activation of a cryptic mitochondrial targeting signal at residues
33-44 by sequence specific cleavage past the 4th and 32nd residues of the protein by a cytosolic endoprotease (11, 15, 16). In the present
study, the sequence specificity of 1A1 chain cleavage by endoprotease
and the generality of the mechanism of P450MT2 biogenesis was further
tested by purifying and characterizing the 1A1-like P450 from
BNF-treated rat brain mitochondria. Our results show that the brain
mitochondrial P450MT2 is truncated at the same position as the major
liver mitochondrial forms. Furthermore, under chronic BNF treatment
conditions both in rat brain and cultured C6 glioma cells, the
mitochondrial P450MT2 continues to accumulate and become a major
part of the total 1A1 pool. The brain mitochondrial form exhibited high
N-demethylation activity with a variety of antidepressant and anticonvulsant drugs suggesting a role in modulating the pharmacological potencies of neuroactive drugs.
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MATERIALS AND METHODS |
Treatment of Animals and Subcellular Fractionation of
Tissues--
Maintenance of male Harlan Sprague-Dawley rats (100-150
g, Harlan Sprague-Dawley Inc., Indianapolis, IN) received
intraperitoneal administration of BNF (80 mg/kg body weight in corn
oil) once daily for either 4 or 10 days, as described (4). The control rats were administered with equivalent amounts of corn oil.
Animals were killed 24 h after the last injection and overnight
fasting by CO2 asphyxiation, and perfused transcardially
with ice-cold saline. The livers and brains were rapidly removed,
rinsed with saline excised in sucrose-mannitol buffer (2 mM
HESES, pH 7.4, 70 mM sucrose, 220 mM mannitol,
and 2 mM EDTA). Liver mitochondria were isolated as
described (17). Microsomes were isolated from the post-mitochondrial
supernatant by centrifugation at 120,000 × g for
1 h at 4 °C. Brain mitochondria were isolated using
discontinuous Percoll density gradient banding as described by Sims
(18). Briefly, brains were homogenized in 10 volumes of isolation
medium containing 0.32 M sucrose, 0.1 mM
phenylmethylsulfonyl fluoride, 1 mM EDTA, 0.1 mM DTT, and 0.1 M Tris-HCl buffer, pH 7.4, and centrifuged at 1,300 × g for 3 min. The supernatant
was centrifuged at 21,000 × g for 10 min. The
resultant pellet was resuspended in isolation medium and purified by
banding through a discontinuous Percoll gradient. Mitochondria were
suspended in sucrose/mannitol buffer (50 mg of protein/ml) and treated
with digitonin (Wako Chemicals) at a final concentration of 75 µg/mg
protein. The mitochondrial suspension was shaken on ice for 5 min, and
the mitoplasts were pelleted by centrifugation at 12,000 × g for 10 min. The mitoplast pellet was washed 4 times with
the sucrose/mannitol buffer, and used for further analysis. The purity
of the mitochondrial preparation was checked routinely by assaying the
marker enzyme activities and by immunoblot analysis as described before
(10, 19). The purity of digitonin was found to be a critical factor in
the yield as well as quantity of mitoplasts from brain tissue. In our
hands, digitonin from Wako Chemicals yielded satisfactory results. The P450 content of mitoplasts was measured by the sodium
dithionite-reduced carbon monoxide binding difference spectra (20) in a
buffer system containing 100 mM
KH2PO4, pH 7.4, 20% glycerol (v/v), 0.5% sodium cholate (w/v), and 0.4% Triton N-101 (v/v) for measuring the
P450 content.
Solubilization and Purification of Brain Mitochondrial
P450MT2--
Mitoplasts from 10-day BNF-treated rat brain were
suspended in 100 mM KH2PO4 buffer,
pH 7.4, containing 20% glycerol, 1 mM EDTA, and 1 mM DTT, at a final concentration of 20 mg of protein/ml and
sonicated for 3 min (30 s pulse followed by 60 s of standing on
ice) at setting 6 of a Branson sonifier. The P450 was solubilized by
adding sodium cholate to a final concentration of 0.8% and fractionated with PEG as described previously (6). The 0-15% PEG
precipitate was collected by centrifugation at 100,000 × g for 1 h and the pellet was suspended in 100 mM KH2PO4, pH 7.4, containing 20%
glycerol, 1.0 mM EDTA, 1.0 mM DTT, and 0.5%
sodium cholate. The proteins were dissolved by homogenization with a glass homogenizer followed by stirring the suspension for 30 min at
4 °C. The solubilized protein fraction (10 mg of protein/ml) was
subjected to 
-octylamine-agarose column chromatography as described
before (7, 8). The column was first washed until the
A280 of the eluant reached <0.05, and the
protein bound to the column was eluted successively with 10 column
volumes of buffer A containing 0.2 and 0.5% emulgen, respectively.
Fractions rich in P450 (>0.1 Å at 417 nm) were pooled and
concentrated by ultrafiltration through Amicon filters. The
concentrated samples were dialyzed overnight against three changes of
buffer B (10 mM KH2PO4 buffer, pH
7.7, 20% glycerol, 0.2% sodium cholate, and 0.2% emulgen), and
subjected to further purification by Adx-Sepharose chromatography (12).
Coupling of purified Adx to Sepharose matrix was carried out as
described by Honukoglu et al. (21). Briefly, human
recombinant Adx (0.1 µmol) was conjugated to 15 ml of CNBr-activated
Sepharose 4B (7 ml bed volume) by incubating at 4 °C for 24 h.
The P450 purified by -octylamine-agarose chromatography (10 mg/ml
suspension of 40-60% purity) in 10 mM
K2HPO4 buffer, pH 7.4, containing 10% glycerol, 0.1% sodium cholate, 0.1 mM EDTA, 0.1 mM phenylmethylsulfonyl fluoride, 0.1 mM DTT
(buffer C) was loaded on to Adx-Sepharose column (5 ml bed volume),
pre-equilibrated with buffer C. The column was washed with 10 volumes
of the same buffer and the bound proteins were eluted with a step
gradient of 5 ml each containing 50, 100, 150, and 200 mM
KCl in buffer C. The fractions were monitored for their absorbence at
417 nm.
Growth and Treatment of C6 Glioma Cells--
Rat glioma C6 cells
were grown as described before (22) in Ham's F-10 medium with 15%
horse serum and 2.5% fetal bovine serum as described in the ATCC
manual. BNF was dissolved in Me2SO and added in fresh
medium alternate days for 4 days beginning from the 4th day of the
passage. BNF in 0.1% Me2SO was added to a final
concentration of 50 µM. Control plates were treated with an equivalent volume of 0.1% Me2SO alone. In chronic BNF
treatment experiments, after 72 h of initial treatment, cells were
replated and continuously exposed to BNF for up to 192 h. Cells
were homogenized in 10 volumes of homogenization buffer (10 mM Tris-HCl, pH 7.4, 150 mM KCl, 10 mM EDTA, 1 mM DTT, and 0.25 mM
phenylmethylsulfonyl fluoride), with a Potter-Elvehjem Teflon-glass
homogenizer. Microsomes and mitochondria were isolated by differential
centrifugation as described (17). Mitochondria were further purified on
discontinuous Percoll density gradient as described earlier (18) and
washed twice with the homogenization buffer to eliminate contaminating Percoll and used for analysis.
Polyacrylamide Gel Electrophoresis and Immunoblot
Analysis--
Proteins were analyzed on 12% SDS-polyacrylamide gels
and visualized by staining with Coomassie Brilliant Blue (24) or
subjected to immunoblot analysis. In some experiments proteins were
also subjected to high-resolution gradient (14-16%)
SDS-polyacrylamide gels for resolving different P450MT2 forms as
described (15). The conditions of protein blotting and immunodetection
of protein bands were as described (15, 25). Rabbit polyclonal
antibodis raised against purified rat liver mitochondrial P450MT2 (10) or intact P4501A1 (Amersham Pharmacia Biotech, Piscataway, NJ) were used.
NH2-terminal Sequencing--
The Adx-Sepharose
affinity purified cytochrome P450 (~100 pmol) was run on a gradient
SDS-polyacrylamide gel (14-16%) and transblotted onto Sequi-blot
polyvinylidene difluoride membrane (Bio-Rad). The amino acid sequence
of the two differently migrating protein components was determined by
the phenylthiohydantion procedure in a Beckman LH 3600 gas-phase sequencer.
Metabolism of Xenobiotic Substrates--
The
N-demethylation of various substrates was measured by
assaying the rate of formaldehyde formation (26, 27). Reactions with
mitoplasts and microsomes were run in a 500-µl final volume in a
buffer containing 50 mM Tris-HCl, pH 7.4, 20 mM
MgCl2, 200 µg of mitochondrial or microsomal protein, and
100 µM substrate. Purified Adx (0.1-0.2 nmol) + Adr
(0.01-0.02 nmol) were added in some reactions with mitoplast
preparations as indicated. Reconstitutions with purified P4501A1 and
P450MT2 were carried out in dilaurylphosphatidyl choline vesicles (7)
using the same buffer system described above for intact membranes. The
final reaction volume was 200 µl, and contained 50 pmol of P450, 0.2 nmol of Adx, and 0.02 nmol of Adr or 0.1 nmol of P450 reductase and 100 µM substrate. After 3 min of preincubation at 37 °C
the reaction was initiated by the addition of 1 mM NADPH
and the reaction was continued at 37 °C for another 20 min in a
shaking water bath. Reactions were terminated by adding 0.5 volume of
ice-cold trichloroacetic acid (10% w/v). The insolubles were pelleted
by centrifugation at 10,000 × g at room temperature.
An aliquot of the supernatant was mixed with an equal volume of Nash
reagent (250 µl or 100 µl) further incubated at 55 °C or 15 min.
The reaction product, formaldehyde, was measured according to the
method of Nash (27). A notable drawback of this assay is a generally
high background value, which can be controlled by using freshly
prepared Nash reagent and controlling the heating step during color
development to 55 °C for 15 min. Typically, we obtained
A412 values in the range of 0.01 to 0.014 for
control tubes without added enzyme, and all significant
N-demethylation activities reported here correspond to >3.5
fold of background reading.
Confocal Immunofluorescence Microscopy--
Rat C6 glioma cells
were grown on coverslips and treated with BNF (50 µM) for
72 or 96 h and processed for antibody staining essentially as
described before (11, 28). After permeabilization with 0.1% Triton
X-100, cells were blocked with 5% goat serum for 1 h at room
temperature. Cells were double immunostained with 1:100 dilution of
rabbit polyclonal antibody to P4501A1 and 1:50 dilution of mouse
monoclonal antibody to the mitochondrial genome encoded human COX I
(Molecular Probes, Eugene, OR) as the mitochondrial-specific marker.
Cells were washed repeatedly with phosphate-buffered saline (10 mM Na2HPO4, pH 7.0, and 150 mM NaCl), and incubated with fluorasceine 5-isothocyanate-conjugated anti-rabbit donkey IgG for the detection of
P4501A1 and Texas Red-conjugated anti-mouse donkey IgG for the
detection of COX I protein. Incubation with both the secondary antibodies (Jackson ImmunoResearch Laboratories) were carried out for
1 h at 37 °C at 1:100 dilution. Unbound secondary antibodies were removed by repeated washing with phosphate-buffered saline. Fluorescence microscopy was carried out under a TCS laser scanning microscope (Leica Inc.). 0.5-µm optical sections were scanned at the
z axis with both fluoresceine 5-isothocyanate and Texas Red
channels fully open to prevent any shifting or distortion of the images.
Protease Protection and Alkaline Extraction--
Freshly
isolated mitochondria and microsomes were subjected to trypsin
digestion as described (10). Mitochondria and microsomes were suspended
in 50 mM potassium phosphate buffer containing 20% (v/v)
glycerol, 0.1 mM EDTA, 0.1 mM DTT and subjected
to trypsin digestion (30 µg of trypsin/mg protein) at room
temperature for 30 min. The reaction was stopped by adding trypsin
inhibitor (300 µg/mg protein) and an equal volume of 2 × Laemmli's sample buffer (24). The samples were incubated in a boiling
water bath for 5 min and loaded onto a 12% SDS-polyacrylamide gel for
immunoblot analysis.
Extraction of mitochondrial and microsomal proteins with 0.1 M Na2CO3 (pH 11), separation of
soluble and insoluble protein fractions, and Western blot analysis were
essentially as described (9, 10), using freshly isolated mitochondria
and microsomes. Except for the protease protection and alkaline
extraction, in all other experiments digitonin-treated mitoplasts were used.
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RESULTS |
Purity of Mitochondrial Preparations--
The purity of rat brain
mitochondrial preparations was routinely tested by immunoblot analysis
for mitochondrial-specific COX I protein and microsome-specific P450
reductase. As shown in Fig. 1 (left
panel), proteins solubilized from mitoplast preparations contained
39-kDa protein cross-reacting with antibody to COX I, while the
microsomal fraction contained negligible COX I protein. As expected,
the microsomal protein contained high levels of P450 reductase (Fig. 1,
right panel), while the mitochondrial preparations contained
negligible 78-kDa protein cross-reacting with antibody to P450
reductase. Although not shown, rat brain mitoplast preparations contained less than 2% microsome-specific marker enzyme,
rotenone-insensitive NADPH cytochrome c reductase, but
nearly 90% of cytochrome c oxidase activity. As previously
shown (4, 7) the rat liver mitoplast preparations used in this study
contained less than 1% microsomal contamination based on marker enzyme
assays.
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Fig. 1.
Purity of brain mitochondrial
preparations. Proteins solubilized from a representative
microsomal and digitonin-treated mitochondrial preparations from rat
brain (75 µg each) were subjected to immunoblot analysis.
A, immunoblot with monoclonal antibody to COX I (1:3000
dilution); and B, polyclonal antibody against rat P450
reductase (1:3000 dilution). The blots were developed using horseradish
peroxidase-conjugated secondary antibodies (1:30,000 dilution) as
described under "Materials and Methods."
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Extent of P450MT2 Induction in Liver and Brain
Mitochondria--
To understand the possible functional significance
of microsomal P4501A1 and mitochondrial P450MT2 in the rat liver and
brain, we determined their relative abundance at moderate 4 days of BNF treatment, and chronic 10 days of BNF treatment. The immunoblot analysis of protein in Fig. 2A
shows that the 1A1 antibody-reactive protein in the rat brain
mitochondria increased steadily at 4 and 10 days of BNF treatment. The
level of antibody-reactive protein in the brain microsomal fraction, on
the other hand, was significantly reduced at 10 days of BNF treatment
after reaching a peak at 4 days. As seen from Fig. 2B, the
induction pattern is nearly similar in the liver; the level increases
steadily in the mitochondrial compartment, while that of the microsomal
compartment peaks at 4 days of treatment followed by a significant
reduction by 10 days of treatment.
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Fig. 2.
Different patterns of induction of P4501A1
antibody-interacting protein in the mitochondrial and microsomal
fractions. Mitochondrial and microsomal isolates (75 µg of
protein in each case) from control, 4- and 10-day BNF-treated rats were
subjected to immunoblot analysis using polyclonal antibody against
P4501A1 (1:3000 dilution) and horseradish peroxidase-conjugated
secondary antibody as described in the legend to Fig. 1 and under
"Materials and Methods." A, subcellular fractions from
brain; and B, subcellular fractions from liver. Percent
tissue distribution in figures. C, liver; and D,
brain were calculated based on the band densities and yield of
mitochondrial and microsomal membranes. Typically we obtained 4.8-5.0
mg of mitoplast and 7.2-7.5 mg of microsomal protein/g (wet weight)
liver tissue, and 3.6-3.8 mg of mitoplast and 5.6-6.1 mg of
microsomal proteins/g (wet weight) brain tissue. The combined
mitochondrial and microsomal antibody reactive protein content, which
amounted to more than 90% of the total tissue content was considered
to be 100% for calculating % distribution.
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The total tissue levels (per gram basis) of mitochondrial and
microsomal 1A1 antibody-reactive proteins in the liver and brain are
presented in Fig. 2, C and D, respectively. These
values were calculated based on the recovery of different organelles
(mg of proteins)/g of tissue. Results show that the rate of
accumulation of 1A1-like protein in mitochondria and microsomes follow
different kinetic patterns. Interestingly both in the liver and brain,
at 10 days of chronic BNF treatment, the mitochondrial P450MT2
preferentially accumulates to reach about 45-57% of the total tissue
pools. The preferential increase of mitochondrial P450MT2 during
chronic exposure to BNF was also investigated in C6 glioma cells, in
which the expression of endogenous P4501A1 gene is induced
in response to chemical inducers. Results of immunoblot analysis (Fig.
3A), and quantitation of
subcellular contents of 1A1 antibody-reactive protein in Fig.
3B, show that similar to that seen with rat brain, the level
of mitochondrial P450MT2 at 96 h of treatment was about 4-fold of
that detected in microsomes. Additionally, at chronic 192 h of
treatment, the mitochondrial P450MT2 represented over 95% of the total
tissue pool, while the level of antibody reactive protein in the
microsomal fraction was drastically reduced.
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Fig. 3.
Relative levels of mitochondrial and
microsomal P450 in BNF-treated C6 glioma cells. Cells were exposed
to BNF for varied lengths of time, mitoplasts, and mitochondria were
isolated and subjected to immunoblot analysis (75 µg of protein each)
as described in the legend to Fig. 2. Cellular distribution in
B was calculated also as described in the legend to Fig. 2.
The overall recovery in terms of protein, mitoplasts (3.4 mg/g cells,
wet weight), and microsome (5.6 mg/g cells, wet weight) did not vary
significantly during the 192 h of treatment.  , represents
mitochondria, and  , represents microsomes. There was no detectable
cell death or growth inhibition by BNF treatment up to 192 h.
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Intramitochondrial Location of 1A1-like Protein in BNF-induced Rat
Brain--
The intramitochondrial location of the antibody-reactive
P450 protein associated with brain mitochondria was investigated using
protease digestion of freshly prepared mitochondria and microsomes from
10-day BNF-treated rat brains. The immunoblot (Fig.
4A) developed with antibody to
P4501A1 shows that trypsin digestion did not affect the level of
antibody-reactive protein in intact mitochondria, suggesting
intramitochondrial location. Similar treatment of brain microsomal
preparations, however, nearly quantitatively eliminated the antibody
reactive protein. Furthermore, as shown in Fig. 4B, the
antibody reactive protein from the mitochondrial fraction was nearly
quantitatively extracted with 0.1 M
Na2CO3, suggesting the membrane extrinsic
nature of the mitochondrial form. The microsome-associated protein, on
the other hand, was completely resistant to alkaline extraction
suggesting a transmembrane orientation. Similar resistance to limited
proteolysis and solubility in alkaline Na2O3
extraction were reported for the rat liver mitochondrial P450MT2
(15).
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Fig. 4.
Distinctive features of brain mitochondrial
P450. In A, freshly isolated mitochondria and
microsomes from 10-day BNF-treated rat brain were subjected to trypsin
digestion as described under "Materials and Methods," and 75 µg
of protein each was subjected to immunoblot analysis using polyclonal
antibody to liver P450MT2. In B, mitoplasts and microsomes
from 10-day BNF-treated rat brain were subjected to alkaline
Na2CO3 extraction as described under
"Materials and Methods." Both soluble and insoluble fractions
equivalent of 100 µg of starting mitochondrial and microsomal
proteins were subjected to immunoblot blot analysis as in A.
In A and B, 2 µg of purified P450MT2 was run as
a control.
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The mitochondrial targeting of P4501A1-like protein in inducer-treated
C6 glioma cells was ascertained by immunohistochemical colocalization
of P450 with mitochondria-specific COX I protein, which is encoded by
the mitochondrial genome. As seen from Fig. 5A (upper panel),
control uninduced cells were stained insignificantly with 1A1 antibody,
while mitochondria-like punctate structures were stained with COX I
antibody. In 72-h BNF-treated cells (middle panel), however,
1A1 antibody yielded intense staining with cytoplasmic organelles, a
majority of which colocalized with structures stained with COX I
antibody, suggesting mitochondrial localization. Some of the 1A1
antibody-stained structures in 96-h BNF-treated cells also colocalized
with organelles stained with bCOP antibody (Fig. 5B). The
latter may represent proteins targeted to plasmamembrane (29, 30).
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Fig. 5.
Mitochondrial localization of P450MT2 in C6
glioma cells treated with BNF. In A, control cells or
cells treated with BNF for 72 h were co-immunostained with 1A1
antibody (left most panel) or COX I antibody (middle
panel). In B, cells treated with BNF for 96 h were
co-immunostained with 1A1 antibody (left most panel) and
bCOP antibody (middle panel). The right most
panels in A and B represent overlay of
double immunostained patterns. Details of immunostaining and microscopy
were as described under "Materials and Methods."
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Characterization of Brain Mitochondrial P450MT2--
Use of high
resolution gradient gel, followed by immunoblot analysis (Fig.
6), resulted in the resolution of two
distinctly migrating P4501A1 antibody interacting species from both
liver and brain mitochondria of BNF-induced rats. The two brain forms resolved in this study resembled the previously identified liver forms,
the latter designated as P450MT2a and MT2b (11, 12). The faster
migrating species identified from the brain mitochondria co-migrated
with bacterially expressed +33/1A1 as well as purified liver
mitochondrial P450MT2b, while the slow migrating protein co-migrated
with microsomal P4501A1, or bacterially expressed +5/1A1 (latter result
not shown). These results suggest the P4501A1 molecular forms targeted
to brain mitochondria are similar to the liver mitochondrial forms.
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Fig. 6.
Resolution of brain mitochondrial P450MT2 on
gradient polyacrylamide gels. Liver and brain mitoplasts, and
brain microsome from 10-day BNF-treated rats (75 µg each) were
subjected to immunoblot analysis on a 14-16% gradient polyacrylamide
gel as described under "Materials and Methods." Purified liver
MT2b, liver microsomal P4501A1, and bacterially expressed/purified
+33/1A1 (2 µg each) were run alongside as controls. The bands were
visualized by staining with Coomassie Brilliant Blue.
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With a view to determine the molecular characteristics of the brain
mitochondrial P450MT2 and to identify site(s) of proteolytic processing
we purified P450MT2 from 10-day BNF-treated rat brain mitochondria. The
purification scheme was modified from the one used for the purification
of the liver mitochondrial forms (6), and consisted of a combination of
PEG fractionation, chromatography on OAA column (7, 8), and affinity
binding to Adx-Sepharose resin (12). The purification steps and the
recovery of total proteins and P450 content at individual steps are
listed in Table I. It is seen that nearly
72% of the mitochondrial P450 was solubilized with sodium cholate and
nearly 60% of the solubilized P450 was recovered in the 15% PEG
precipitate. A significant portion of P450 (15% of input) loaded on
the OAA column was eluted with 0.2% Emulgen, while nearly half of
input P450 was eluted as brown-colored material with 0.5% Emulgen. The
former fraction, however, did not contain proteins in the size range of
~50 kDa on SDS-polyacrylamide gels (results not shown). We therefore
used the 0.5% Emulgen-eluted fraction for further purification by Adx
affinity chromatography. A small fraction (about 2%) of input P450 was
eluted with 50 mM KCl-containing buffer from the Adx
column, while about 20% of input P450 was eluted with 100 mM KCl-containing buffer. Although not shown, no
significant P450 was eluted with 150 and 200 mM KCl
containing buffers. The 100 mM KCl eluate showing highest specific activity of 13.7 nmol of P450/mg of protein represents about
35-40-fold purification.
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Table I
Purification of rat brain mitochondrial P450MT2
Protein content was measured by the method of Bradford
(31), and P450 content was assayed by CO-reduced
spectra as described under "Materials and Methods."
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The SDS-polyacrylamide gel pattern in Fig.
7A shows that both sodium
cholate solubilized and PEG-precipitated fractions contained a number
of protein species detected in the total mitochondrial protein. The
P450-rich fraction eluted from the OAA column at 0.5% Emulgen
contained a prominent band of about 54 kDa in addition to a number of
less prominent bands, suggesting a 50-60% purity. The fraction eluted
from the Adx column with 50 mM KCl-containing buffer
(lane 5) resolved as a 54-55 kDa species. Although this fraction showed a reduced CO spectrum suggesting the presence of P450,
the protein recovery was too low for further analysis. The protein
eluted from the Adx column with 100 mM KCl-containing buffer with a specific activity of 13.7 nmol of P450/mg of protein resolved as a major band with apparent molecular mass of 54 kDa (lane 6), and appeared about 85% pure. SDS-polyacrylamide
gel pattern of the purified fraction on a 14-16% gradient gel (Fig. 7B) resulted in the resolution of two differently migrating
protein species similar to that observed with purified liver
mitochondrial P450MT2. The faster migrating MT2b is the major component
representing about 60-70% of the protein fraction and the slower
migrating MT2a is a minor component. Although not shown, both of these
proteins cross-reacted with antibody to P4501A1 in immunoblot blot
analysis.
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Fig. 7.
Electrophoretic resolution and
NH2-terminal sequence of purified brain P450MT2. In
A, protein fractions at various stages of purification from
Table I were subjected to electrophoresis on a 12% polyacrylamide gel.
Lane M, molecular weight marker; lane 1, 75 µg
of total mitoplast protein; lane 2, 30 µg of cholate
solubilized fraction; lane 3, 75 µg of 15% PEG
precipitate; lane 4, 20 µg of -octylamine-agarose
column fraction eluted with 0.5% Emulgen; lane 5, 1 µg of
protein eluted from Adx-Sephraose column with 50 mM
KCl-containing buffer; and lane 6, 2 µg of protein eluted
from Adx-Sepharose column with 100 mM KCl-containing
buffer. In B, 2 µg of protein eluted from Adx-Sephraose
column with 100 mM KCl-containing buffer was resolved on a
14-16% gradient polyacrylamide gel. Protein bands were visualized by
staining with Coomassie Brilliant Blue. C shows the
NH2-terminal sequence of P450MT2a (slower migrating band)
and MT2b (faster migrating band) from B, compared with
microsomal P4501A1.
|
|
As shown in Fig. 7C, NH2-terminal sequence
analysis of the faster migrating MT2b protein yielded sequence
identical to the liver mitochondrial P450MT2b, starting with the 33rd
residue of the microsomal P4501A1. The slower migrating band yielded
sequence similar to the liver mitochondrial MT2a. These results suggest the specificity of the endoprotease processing in different tissues.
Catalytic Activities of the Brain Mitochondrial P450MT2--
To
gain further insight into the functional and molecular differences
between the mitochondrial P450MT2 and microsomal P4501A1, we tested
ERND activity of the two membrane isolates. We also tested a number of
neuroactive drugs, amitriptilyne and imipramine, diazapam, morphine,
and lidocaine. These substrates have been previously shown to be
metabolized by various microsomal P450s, other than P4501A1 (32).
Mitoplasts from untreated brain showed marginal activities of 0.8-1.4
nmol/mg of protein with all six substrates, which was marginally
increased by adding Adx + Adr proteins (Fig.
8, A and B).
Mitoplasts from 4-day BNF-treated rats showed activities of about
1.6-2 nmol/mg of protein for all six substrates, and the activities
were increases 2-fold by adding Adx + Adr proteins. Consistent with the
increased P450MT2 content in Fig. 2, mitoplasts from 10-day BNF-treated
brain showed even higher activities of 8-9 nmol/mg of protein/min with
all six substrates in the presence of added Adx and Adr proteins. The
microsomal fractions from untreated rat brain reconstituted with
endogenous P450 reductase, on the other hand, showed marginal activity
of 1.0-1.5 nmol/mg/min. The microsomal activity for none of the
substrates increased both at 4 and 10 days of BNF treatment. Thus,
while the increase of N-demethylation activities with all
six substrates in BNF-induced mitochondria was nearly proportional to
the extent of steady state increase in mitochondrial P450MT2, the
microsomal activities did not change in response to both increase of
P4501A1 at 4 days of BNF treatment or a drastic reduction of P4501A1 at 10 days of treatment. These results suggest that the observed N-demethylation activities in the microsomal fraction may be
due to other constitutively expressed P450 forms.
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Fig. 8.
N-Demethylation activities of
mitoplasts and microsomes from BNF-induced rat brains. Mitoplasts
(A and B) and microsomes (C) were
isolated from control, 4- and 10-day BNF-treated rat brains and assayed
for N-demethylation activities using indicated substrates
(100 µM each), as described under "Materials and
Methods." Assays with mitoplast preparations were carried out with or
without added Adx and Adr (0.2 nM Adx and 0.02 nM Adr) with a view to counter the possible loss of these
soluble proteins during isolation and gradient banding. In the case of
microsomal fraction the endogenous P450 reductase served as electron
donor protein. The values represent average ± S.E.
(n = 4). In C, A = amitriptyline, E = erythromycin, D = dizapam, I = imipramine, L = lidocaine,
M = morphine.
|
|
To further ascertain the role of P450MT2 in the metabolism of the
various neuroactive drugs described above, we carried out reconstitution of purified P450MT2 with these substrates. Table II shows the results of ERND activity
reconstituted with purified P4501A1 and brain mitochondrial P450MT2.
P4501A1 in the presence of P450 reductase system yielded very low
activity of 0.05 nmol/nmol of P450/min. As expected, P450MT2 in the
presence of NADPH and Adx + Adr yielded the highest activity of 2.5 nmol/nmol of P450/min. The activity was highly dependent on the
addition of electron transfer proteins, as well as NADPH. Furthermore,
the ERND activity was inhibited by both CO and a P450 inhibitor,
SKF525-A, confirming that the observed ERND activity is catalyzed by
P450. Finally, as shown for the liver mitochondrial enzyme, the
purified brain P450MT2 yielded 1.3 nmol/nmol of P450/min activity when
reconstituted with P450 reductase. As seen from Fig.
9, the brain P450MT2 also exhibited high
activities in the range of 2.5-2.6 nmol/nmol of P450/min with all of
the other substrates in Adx + Adr-supported systems, and nearly half
the activities in P450 reductase-supported systems. Although not shown,
purified microsomal P4501A1 yielded uniformly low activities
(0.02-0.03 nmol/nmol of P450/min) with all of the substrates in a P450
reductase-supported system. However, as expected (33), purified P4501A1
yielded high EROD (6 nmol/nmol of P450/min) activity in a P450
reductase-supported system. These results suggest the possibility that
P450MT2 may play an important role in the metabolism/inactivation of an
array of neuroactive drugs and pain suppressants. These results also
support the possibility that different electron donor proteins or mode
of electron channeling may influence substrate oxidation.
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Table II
Reconstitution of erythromycin N-demethylation activity with
purified P450s
Reconstitution was carried out in the presence of
dilarylphosphatidylcholine liposomes as described under "Materials
and Methods." CO was gently bubbled through the enzyme suspension for
45 s (@60 bubbles/min) and control enzyme was bubbled through
N2 at the same rate. SKF525-A was added at a final
concentration of 1 mM. The values represent average
mean ± S.E. (n = 4).
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Fig. 9.
Metabolism of neuroactive substrates by
purified brain P450MT2. Reconstitution of enzyme activity was
carried out in dilaurylphosphatidyl choline liposome vesicles in the
presence or absence of added 0.2 nM Adx + 0.02 nM Adr or 0.1 nM P450 reductase as described
under "Materials and Methods." N-Demethylation
activities were assayed using 100 µM each of the
indicated substrates also as described under "Materials and
Methods." The values represent average ± S.E.
(n = 4). A = amitriptyline,
D = dizapam, I = imipramine,
L = lidocaine, M = morphine.
|
|
| |
DISCUSSION |
The molecular characteristics of P450MT2 (SWISS-PORT
P10085) H2-terminal truncated P4501A1 from rat liver
mitochondria has been extensively studied, although the nature of its
counterparts from other rat tissues remain unclear. Recent studies from
our laboratory showed that 10 days of chronic BNF administration
resulted in a significant induction of 1A1 antibody-reactive protein in lung mitochondria (16), although a low abundance of the protein in the
lung even under induced conditions prevented its detailed analysis. In
the present study, we have therefore investigated the nature of P4501A1
targeted to rat brain mitochondria under moderate 4 days of treatment
and 10 days of chronic treatment with BNF. A number of studies have
shown the constitutive expression of P4501A1 in the rat
brain (34-40). Similarly, induction of P4501A1 gene
expression in the brain and also C6 glioma cells by
2,3,7,8-tetrachlorodibenzo-p-dioxin, and different
polycyclicaromatichydrocarbons has been extensively studied (17, 18,
34, 36-40). However, the relative abundance and distribution of this
P450 in different cytoplasmic organelles, particularly microsomes and
mitochondria of inducer-treated rat brains, remains unclear. Using a
prototype CYP1A1 inducer, BNF, we show that the accumulation
of antibody-reactive protein in the microsomes and mitochondria follow
different kinetic patterns. The microsomal P450 content peaks at 4 days
of treatment, followed by a sharp decline by 10 days of chronic
treatment. The mitochondrial content, on the other hand, shows a steady
time-dependent increase to reach nearly half of the total
tissue pool by 10 days of BNF treatment. To avoid possible pain and
suffering due to longer BNF treatment regimens in animals, we used rat
glial cell line to investigate the effects of prolonged treatment with
BNF. It is noteworthy that, by 192 h exposure of cells to BNF, the
mitochondrial P450 pool reaches over 95% of the total cellular pool,
suggesting an important physiological function for mitochondrial
P450MT2. The 50 µM BNF used in this study neither
affected cell morphology nor caused cell death (results not shown).
Although reasons for the steady accumulation of mitochondrial form are
not clear, an increased cytoplasmic endoprotease activity during
chronic BNF treatment could be a contributing factor. Different protein
turnover rates in these two membrane compartments may also be an
important factor. Unpublished
results2 in our laboratory
show a dramatic increase in cytosolic endoprotease activity in both rat
brain and C6 glioma cells chronically treated with BNF. Currently
efforts are underway to purify this protease.
Because of the problems of cross-contamination generally inherent in
most mitochondrial isolation procedures, we have used the gradient
banding method (18) followed by digitonin treatment for the isolation
of mitochondria. The resultant mitoplasts contain no detectable
microsomal specific marker protein, P450 reductase (Fig. 1), and less
than 0.6% microsomal specific NADPH cytochrome c reductase
(rotenone insensitive). Furthermore, mitochondrial location of the
antibody reactive P450, and the similarity of brain
mitochondria-associated P450 with the well characterized liver
mitochondrial P450MT2 were established using multiple criteria: 1) the
mitochondrial associated P450 was resistant to limited protease
digestion, while that associated with the microsomal membrane was
highly sensitive to similar treatment conditions (Fig. 4A).
2) Immunohistochemical analysis showed that in BNF-treated C6 glioma
cells, 1A1 antibody stained a large population of punctate membrane
structures, which were co-localized with membrane structures stained
with COX I antibody, suggesting mitochondrial location (Fig. 5).
Notably, some of the 1A1 antibody-stained structures also co-localized
with more rounded vesicular structures stained with antibody to
Golgi-specific protein, bCOP. However, both in terms of abundance and
shape these latter membrane structures appeared distinct from
structures overlapping with mitochondrial membranes in Fig.
5A. 3) Similar to that demonstrated for the liver P450MT2,
the brain mitochondria-associated P450 resolved as two distinctly
migrating components on gradient polyacrylamide gels (Fig. 6). 4) The
1A1 antibody reactive protein associated with brain mitochondria was
readily extractable with alkaline Na2CO3 buffer
suggesting membrane extrinsic orientation, as opposed to insolubility
in alkaline buffer and transmembrane orientation of the
microsome-associated P450 (Fig. 4B). These results are consistent with the properties previously described for liver mitochondrial P450MT2 and suggest a true mitochondrial targeted counterpart in the brain.
To further ascertain the molecular characteristics and also to study
its catalytic properties, we purified the mitochondria-associated P450
using a combination of PEG fractionation, -octylamine-agarose chromatography, and Adx affinity binding methods. We believe that a
superinducibility of the mitochondrial P450 by chronic BNF treatment coupled with the effective solubilization of P450 were important factors toward the successful purification of the brain P450MT2. It
should be pointed out that our previous attempts at purifying this form
using intact brain mitochondrial preparations were unsuccessful mainly
due to poor solubilization of P450. Thus, use of digitonin-stripped mitoplast was critical for the effective solubilization by sonic disruption and cholate treatment as used in this study. Although a
partial purification of P4501A1 from induced rat brain microsome was
reported previously (41), this is probably the first successful isolation of the brain mitochondrial form to near homogeneity. The
purified P450MT2 resolved as two distinct components similar to that
shown for the liver mitochondrial counterpart, and yielded NH2-terminal sequence identical to P450MT2a, starting with
residue 5, and MT2b, starting with residue 33 of P4501A1. These results confirm the specificity of the cytoplasmic endoprotease, which may be
an important regulatory factor in modulating the cellular level of
P450MT2. Although not shown, both human and mouse counterparts of
P4501A1 show similar cytoplasmic protease processing and mitochondrial targeting, confirming the generality of the targeting mechanism described for the rat liver P450MT2 (11).
Studies on the xenobiotic substrate metabolism by brain P450 have
largely focused on the microsomal fraction (23, 34-36, 39, 40, 42).
Microsomes from both inducer-treated rat brain and C6 glioma cells show
high EROD activity (34-36), a marker for P4501A1. Although not shown,
consistent with these reported results we also observed high EROD (0.4 nmol/mg of protein/min) activity with microsomes from BNF-treated brain
and also C6 glioma cells. Interestingly, both intact mitoplasts from
BNF-treated rat brain and purified brain P450MT2 showed ERND activity,
which is not a marker for parent P4501A1. The ERND activity of
mitoplast preparations increased 3-fold by adding Adx + Adr. Similarly,
the purified P450MT2 showed nearly 2-fold higher activity (Table II) in
an Adx + Adr supported system as compared with the activity in a P450
reductase-supported system, suggesting a preference for the former
electron donor system. The ERND activity of the purified enzyme
represents a true monooxygenase activity based on inhibition by CO and
SKF525-A, and dependence on NADPH, as well as requirements for electron
transfer proteins (Table II). Although not shown, P450MT2 both as part
of intact mitoplasts or in purified form showed relatively low EROD
activity when reconstituted with both electron donor protein systems.
These results confirm and extend our previous observations with liver
P450MT2 (11, 12, 15) that NH2-terminal truncation and the
new mitochondrial environment affect both substrate binding specificity
and electron transfer protein binding ability of the enzyme.
An important finding of this study is that mitochondrial targeted rat
brain P450MT2 exhibited N-demethylation activity for a
number of neuroactive drugs. Amitriptyline and imipramine are widely
used tricyclic anti-depressants. These MAO inhibitors are also known to
affect serotonin uptake (43, 44). Diazepam is an anti-convulsant drug,
which facilitates GABA uptake acting through benzodizapene receptors
(44). These compounds are known to be metabolized by the 2C and 3A
family P450s (44). We also tested an opiate, morphine, and an
anesthetic lidocaine. Microsomal 2B family enzymes are implicated in
the metabolism of these substrates (3). It was surprising that
mitochondria from BNF-induced brain and also purified P450MT2 showed
high N-demethylation activities for all five compounds
tested. Interestingly, mitoplasts from 4- and 10-day BNF-treated brains
showed activities consistent with the extent of MT2 induction. The
dependence of N-demethylation activities in all cases on
added Adx is most likely due to the loss of this soluble protein from
the organelle during isolation and gradient banding. Based on the
mitochondrial P450 content of 0.3 nmol/mg of protein at 10 days of BNF
treatment, the mitochondrial P450MT2 in its native membrane setting
yielded nearly 10-fold higher activity as compared with the purified
enzyme. This marked difference in activity is consistent with a
previous observation that purified/reconstituted P450c27 yielded
considerably lower activity than the native mitochondrial enzyme (16)
and point to the possible involvement of yet unidentified mitochondrial cofactor(s) for activity. It should be noted that the microsomal fraction from control brain showed only about 1.3-1.5 nmol/mg of
protein/min activity that did not show any increase by both 4 and 10 days of BNF treatment. It is likely that the basal level of microsomal
N-demethylation activity is due to endogenous P450s other
than P4501A1. The activity with isolated mitoplasts and purified
enzyme, on the other hand, appear to be due to P450MT2, as they were
effectively inhibited by P4501A1 antibody (results not shown). Based on
the relative activities and mitochondrial and microsomal contents we
estimate that at the chronic 10-day induction, the mitochondrial
activity for the metabolism of these neuroactive substrates represents
about 85% total tissue activity.
Results reported in this study suggest an important physiological
function for mitochondrial P450MT2 in modulating the pharmacokinetics and pharmacodynamics of a family of antidepressants, anticonvulsants, opiates, and other neuroactive drugs. We believe that the 10-day BNF
treatment used in this study mimics the human and animal population chronically exposed to polycyclicaromatichydrocarbons, cigarette smoke,
and related pollutants. For these reasons, the individual's P450MT2
level should be an important consideration in the proper selection of
antidepressant and anticonvulsant drugs, as well as in determining the
drug dose.
| |
ACKNOWLEDGEMENTS |
We thank members of the Avadhani laboratory
for helpful suggestions during this investigation and criticisms on the manuscript.
| |
FOOTNOTES |
*
This work was supported by National Institutes of Health
Grant GM34883.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
Contributed equally to the results of this paper.
§
Present address: Dept. of Experimental Oncology, St Jude
Children's Research Hospital, 332 North Lauderdale, Memphis, TN 38105.
¶
To whom correspondence should be addressed. E-mail:
narayan@vet.upenn.edu; Fax: 215-573-6651.
Published, JBC Papers in Press, July 27, 2000, DOI 10.1074/jbc.M004431200
2
E. Boopathi, H. K. Anandatheerthavarada,
S. V. Bhagwat, G. Biswas, J-K. Fang, and N. G. Avadhani,
unpublished results.
| |
ABBREVIATIONS |
The abbreviations used are:
P450, cytochrome P450;
P450 reductase, NADPH cytochrome P450 reductase;
Adx, adrenodoxin;
Adr, adrenodoxin reductase;
BNF, -naphthoflavone;
COX
I, cytochome c oxidase subunit I;
ERND, erythromycin
N-demethylase;
OAA, -octylamine-agarose;
PEG, polyethyleneglycol (average molecular weight 8000);
EROD, ethoxyresorufin O-deethylase;
DTT, dithiothreitol.
| |
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