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Molecular and Cellular Biology, September 2001, p. 6322-6331, Vol. 21, No. 18
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.18.6322-6331.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Cytochrome P450 Epoxygenase Metabolism of
Arachidonic Acid Inhibits Apoptosis
Jian-Kang
Chen,1
Jorge
Capdevila,1,2 and
Raymond C.
Harris1,*
Departments of
Medicine1 and
Biochemistry,2 Vanderbilt University,
Nashville, Tennessee
Received 2 May 2001/Accepted 1 June 2001
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ABSTRACT |
The ubiquitous cytochrome P450 hemoproteins play important
functional roles in the metabolism and detoxification of foreign chemicals. However, other than established roles in cholesterol catabolism and steroid hormone biosynthesis, their cellular and/or organ physiological functions remain to be fully characterized. Here we
show that the cytochrome P450 epoxygenase arachidonic acid
metabolite 14,15-epoxyeicosatrienoic acid (14,15-EET) inhibits apoptosis induced by serum withdrawal, H2O2,
etoposide, or excess free arachidonic acid (AA), as determined by DNA
laddering, Hoechst staining, and fluorescein isothiocyanate-labeled
annexin V binding. In the stable transfectants (BM3 cells) expressing a
mutant bacterial P450 AA epoxygenase, F87V BM3, which was genetically
engineered to metabolize arachidonic acid only to 14,15-EET, AA did not
induce apoptosis and protected against agonist-induced apoptosis.
Ceramide assays demonstrated increased AA-induced ceramide production
within 1 h and elevated ceramide levels for up to 48 h, the
longest time tested, in empty-vector-transfected cells (Vector cells)
but not in BM3 cells. Inhibition of cytochrome P450 activity by
17-octadecynoic acid restored AA-induced ceramide production in
BM3 cells. Exogenous C2-ceramide markedly increased apoptosis in
quiescent Vector cells as well as BM3 cells, and apoptosis was
prevented by pretreatment of Vector cells with exogenous 14,15-EET and
by pretreatment of BM3 cells with AA. The ceramide synthase inhibitor
fumonisin B1 did not affect AA-induced ceramide production and
apoptosis; in contrast, these effects of AA were blocked by the neutral
sphingomyelinase inhibitor scyphostatin. The pan-caspase inhibitor
Z-VAD-fmk had no effect on AA-induced ceramide generation but abolished
AA-induced apoptosis. The antiapoptotic effects of 14,15-EET were
blocked by two mechanistically and structurally distinct
phosphatidylinositol-3 (PI-3) kinase inhibitors, wortmannin and
LY294002, but not by the specific mitogen-activated protein kinase
kinase inhibitor PD98059. Immunoprecipitation followed by an in vitro
kinase assay revealed activation of Akt kinase within 10 min after
14,15-EET addition, which was completely abolished by either wortmannin or LY294002 pretreatment. In summary, the present studies demonstrated that 14,15-EET inhibits apoptosis by activation of a PI-3 kinase-Akt signaling pathway. Furthermore, cytochrome P450 epoxygenase promotes cell survival both by production of 14,15-EET and by metabolism of
unesterified AA, thereby preventing activation of the neutral sphingomyelinase pathway and proapoptotic ceramide formation.
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INTRODUCTION |
Arachidonic acid is an important
constituent of cellular membranes that is esterified to the
sn-2 position of glycerophospholipids. Under normal
conditions, the concentration of free, nonesterified arachidonic acid
is nearly undetectable, and its release is under tight metabolic and
physiologic control. As an important component of the signaling
pathways of many receptor-mediated processes, specific phospholipases
are activated, and arachidonic acid is released from selected lipid
stores and metabolized by cyclooxygenases and/or lipoxygenases to
potent bioactive lipid mediators such as prostanoids, thromboxanes,
leukotrienes, lipoxins, or hydroxyeicosatetraenoic acids (HETEs)
(38, 49). Numerous cellular responses have been attributed
to cyclooxygenase- and lipoxygenase-dependent pathways, including
regulation of cell growth and induction or inhibition of apoptosis
(4, 26, 45, 54).
In addition to cyclooxygenase and lipoxygenase pathways, cytochrome
P450 also catalyzes the in vivo metabolism of arachidonic acid to
biologically active compounds by three types of NADPH-dependent oxidative reactions (12): (i) olefin epoxidation produces
5,6-, 8,9-, 11,12-, and 14,15-epoxyeicosatrienoic acids (EETs), in a regio- and stereo-selective manner; (ii) allylic oxidation generates 5,8,9,11,12,15 HETEs; and (iii) 
- and -1-hydroxylation results in
the formation of 19- and 20-HETEs. Endogenous EETs are biosynthesized in liver, kidney, and many other organs (12, 38) and are
present in human plasma and urine (13, 56). Previous
studies have demonstrated that EETs have potent biological activities,
including modulation of vascular tone (31), glomerular
hemodynamics (53), and regulation of mitogenesis
(17, 32). EETs have been suggested to be an
endothelium-derived hyperpolarizing factor (7). In addition, recent studies have also suggested that EETs serve as intracellular second messengers in vasculature (29) and in
epithelia (6, 18). Cytochrome P450 is the predominant
arachidonic acid metabolic pathway in cells such as the renal proximal
tubule, in which cyclooxygenase and lipoxygenase are expressed at
nearly undetectable levels (3, 21).
In certain cells, free arachidonic acid itself serves as a regulator of
specific cellular processes, including the activation of intracellular
kinases and lipases and modulation of Ca2+ transients
(19, 33, 40). Intracellular concentrations of free
arachidonic acid can be increased in response to oxidant stress and
other stimuli that may induce apoptosis, and increasing evidence shows
that high intracellular concentrations of free arachidonic acid may be
proapoptotic in many cell types (9, 22, 52, 59, 60). Since
cytochrome P450 epoxygenase is a major pathway for metabolism of
arachidonic acid, the present studies were designed to explore the
potential roles and mechanisms of P450-mediated arachidonic acid
metabolism in cell survival.
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MATERIALS AND METHODS |
Reagents and antibodies.
(±)-14,15-Epoxyeicosatrienoic acid
sulfonimide analog was synthesized as previously described (11,
17) and was shown to have biological activities and
concentration responses identical to those of native 14,15-EET in renal
epithelial cells (17). Arachidonic acid was obtained from
NuCheck-Prep, Inc. (Elysian, Minn.). Epidermal growth factor (receptor
grade) was purchased from Collaborative Research (Bedford, Mass.).
Etoposide, PD98059, wortmannin, LY294002, C2-ceramide, Z-VAD-fmk, and
Escherichia coli diacylglycerol kinase were obtained from
Calbiochem (San Diego, Calif.). Fumonisin B1 was from BIOMOL Research
Laboratories, Inc. (Plymouth Meeting, Pa.). [
-32P]ATP
(specific activity, 3,000 Ci/mmol) was from NEN Life Science Products
(Boston, Mass.). Polyclonal anti-Akt antibodies and protein A-agarose
beads were from Santa Cruz Biotechnology (Santa Cruz, Calif.). The
fluorescein isothiocyanate (FITC)-labeled annexin V binding kit was
from Oncogene Research Products (Cambridge, Mass.). Histone H2B was
from Boehringer Mannheim (Laval, Canada). Scyphostatin was a generous
gift from Takeshi Ogita (Sankyo Co. Ltd., Tokyo, Japan) (42,
43). All other chemicals were from Sigma (St. Louis, Mo.).
Cell culture.
LLCPKcl4, an established adherent proximal
tubule-like epithelial cell line derived from pig kidney
(1), was routinely cultured in Dulbecco's modified Eagle
medium-F-12 medium supplemented with 100 U of penicillin per
ml, 100 µg of streptomycin per ml, and 10% fetal bovine serum
(Hyclone Laboratories, Logan, Utah) at 37°C in a 5% CO2
cell culture incubator. The medium was changed every 2 to 3 days.
Determination of apoptosis.
The following four markers of
apoptosis were utilized.
(i) Cell survival assay.
LLCPKcl4 is an adherent epithelial
cell line that will begin to undergo apoptosis if cultured in the
absence of fetal bovine serum or growth factors for >4 days. For these
studies, LLCPKcl4 cells grown to confluence were changed to serum-free
media, and after 48 h, vehicle (dimethyl sulfoxide
[Me2SO]) or 14,15-EET (10 µM) was added every 3 days.
The cells were then observed and photographed using phase-contrast
microscopy for up to 4 weeks.
(ii) DNA laddering by agarose gel electrophoresis.
Quiescent
LLCPKcl4 cells were treated as indicated in each corresponding
figure. Both adherent and floating cells were then collected,
and genomic DNA was extracted and electrophoresed on a 1.5% agarose
gel containing ethidium bromide and visualized under UV illumination.
(iii) Hoechst 33258 staining.
Morphological assessment of
apoptosis was made after Hoechst 33258 dye staining as described
elsewhere (20, 41). Briefly, quiescent cells were treated
with the test agents and scraped into the culture medium. Both adherent
and nonadherent cells were harvested, washed twice with
Ca2+- and Mg2+-free phosphate-buffered saline
and fixed with cold 100% methanol. Cells were stained with 1 µg of
Hoechst 33258 per ml, mounted in 50% glycerol, and observed under a
fluorescence microscope. Cells with fragmented nuclei were scored as
apoptotic, and a minimum of 500 cells was scored for the incidence of
apoptosis for each data point.
(iv) Detection of phosphatidylserine exposure.
Quiescent
LLCPKcl4 cells grown on coverslips were pretreated with or without the
inhibitors, treated with or without 14,15-EET for 1 h, and then
exposed to H2O2 for 6 h. FITC-labeled
annexin V binding was determined according to the manufacturer's
instructions using a kit from Oncogene Research Products.
Stable transfection of mutant BM3.
We have previously
reported stable transfection of LLCPKcl4 cells with the coding region
of a mutant bacterial P450 from Bacillus megaterium (BM3) in
which phenylalanine 87 was replaced with alanine, converting it to a
stereo- and regioselective epoxygenase (F87V BM3) that generates only
14S,15R-EET from arachidonic acid (18, 28). We utilized these stable transfectants (BM3 cells) as well as empty vector-transfected LLCPKcl4 cells (Vector cells) to
investigate further the cell survival effects of endogenously produced
14,15-EET in the present study.
EET production measurement and stereochemical analysis.
Quiescent BM3 cells and Vector cells were treated with or without
arachidonic acid (30 µM), scraped with the culture medium containing
1 volume of CH3OH, and then mixed with 2 volumes of CHCl3 containing 1 mM triphenylphosphine and an equimolar
mixture of synthetic 14C-labeled 8,9-, 11,12-, and
14,15-EET (55 to 56 mCi/mmol, 30 ng each). After acidification, the
samples were extracted twice and the organic phases were evaporated
under argon. To the resulting residue, 0.5 ml of 0.4 N KOH in 80%
CH3OH was added and the mixture was incubated at 50°C for
60 min. Acidification was followed by extraction into ethylether and
chromatography in SiO2 as described (10). The
EETs were resolved into 14,15-EET and a mixture of 8,9- and 11,12-EET
by reversed-phase high-pressure liquid chromatography and then
derivatized to the corresponding pentafluorobenzyl (PFB) esters by
reaction with PFB bromine. Aliquots of the purified EET-PFB
regioisomers were individually dissolved in dodecane and analyzed by
negative-ion, chemical ionization-gas chromatography-mass spectrometry, utilizing CH4 as the reagent gas, as
described elsewhere (10).
For stereochemical analysis, samples of enzymatically derived
[14C]14,15-EET (25 µg, 1 µCi/µmol) and of synthetic
14R,15S-EET and 14S,15R-EET
were catalytically hydrogenated over PtO2 and esterified using excess PFB bromine, as described elsewhere (10). The
resulting PFB esters were purified by reversed-phase high-pressure
liquid chromatography, and after solvent evaporation, the optical
antipodes of the purified PFB-14,15-EET were resolved by high-pressure
liquid chromatography on a Chiralcel OD column (4.6 by 250 mm)
(J. T. Baker Inc.) with an isocratic mixture of 0.11%
isopropanol-99.89% n-hexane at 1 ml/min with UV monitoring
at 210 nm. The retention times for the PFB esters of synthetic
14R,15S- and 14S,15R-EET were 70.6 and 78.9 min, respectively (28).
Akt kinase activity assay.
Quiescent LLCPKcl4 cells were
treated with the agents indicated in Fig. 3C, cell lysates were
prepared and subjected to immunoprecipitation with a polyclonal
anti-Akt antibody. Immunoprecipitates were utilized for in vitro
protein kinase reactions using histone H2B as a substrate in the
presence of [-32P]ATP at 22°C for 25 min. The
reactions were stopped by addition of 8 µl of Laemmli sample buffer,
and 22-µl aliquots of the reaction mixtures were analyzed by sodium
dodecyl sulfate-polyacrylamide gel electrophoresis. After the gels were
dried, the relative amounts of incorporated radioactivity were
determined by autoradiography.
Ceramide assays.
Quiescent cells were treated with the
indicated agents and lipids were then extracted as described by Van
Veldhoven and Bell (57). Ceramide levels were measured
using the E. coli diacylglycerol kinase assay
(46). Briefly, after the diacylglycerol reaction and
extraction of the labeled lipids, the lower chloroform phase was washed
twice with 1% (wt/vol) HClO4 before drying under nitrogen. The extracts were dissolved in 5% methanol in chloroform and subjected to thin-layer chromatography. After development in a thin-layer chromatography mobile phase of chloroform-acetone-methanol-acetic acid-water (10:4:3:2:1), the plate was air dried and visualized by radioautography.
Statistics.
Data are presented as means ± standard
errors for at least three separate experiments (each in triplicate or
duplicate). An unpaired Student's t test was used for
statistical analysis, and for multiple group comparisons, analysis of
variance and Bonferroni t tests were used. A P
value of <0.05 compared with control values was considered
statistically significant.
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RESULTS |
Antiapoptotic effects of 14,15-EET.
Initial experiments were
designed to investigate the effects of long-term administration of
14,15-EET on the renal epithelial cell line LLCPKcl4. The cells were
grown to confluence and changed to serum-free medium; after 48 h,
vehicle (Me2SO) or 14,15-EET (10 µM) was added every 3 days. As shown in Fig. 1A, the number of
viable cells in vehicle-treated cells diminished progressively, while
the 14,15-EET-treated cells maintained a confluent monolayer with
normal morphology. Virtually 100% of the cells not exposed to
14,15-EET died within 2 weeks; in contrast, with 14,15-EET treatment,
there was no cell death after 2 weeks, and more than 80% of the cells
survived for up to 4 weeks (n = 4).
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FIG. 1.
Antiapoptotic effects of exogenously administered
14,15-EET in LLCPKcl4 cells. (A) 14,15-EET prevented the renal
epithelial cell line LLCPKcl4 from progressive loss of cell viability
caused by serum deprivation. LLCPKcl4 cells grown to confluence were
changed to serum-free medium. After 48 h, vehicle
(Me2SO) or 14,15-EET (10 µM) was added every 3 days.
After 10 days, the majority of the vehicle-treated cells had died while
the 14,15-EET treated cells still maintained a confluent monolayer with
normal morphology. (B) 14,15-EET inhibited DNA laddering induced by
H2O2 or etoposide. After pretreatment with
vehicle (Me2SO) or 14,15-EET (10 µM) for 1 h,
quiescent LLCPKcl4 cells were exposed to H2O2
(500 µM) or etoposide (100 µM) for 24 h, and genomic DNA was
extracted and electrophoresed on a 1.5% agarose gel containing
ethidium bromide. Leftmost lane, 100-bp DNA ladder; rightmost lane,
lambda DNA-HindIII DNA size marker (Promega). (C)
14,15-EET decreased H2O2- or etoposide-induced
apoptotic-cell number; cells were scored for morphological
evidence of apoptosis as described in Materials and Methods.
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Previous studies have indicated that in cultured cell systems the
predominate mechanism of cell death following serum withdrawal
is
through apoptosis, not necrosis (
39). In order to
determine
whether this antiapoptotic effect of 14,15-EET could be
generalized
to agents that acutely induced cell death, quiescent
LLCPKcl4
cells were pretreated with vehicle or 14,15-EET (10 µM) for
1
h and then exposed to H
2O
2 (500 µM) or
etoposide (100 µM). After
24 h, cells were scored for
morphological evidence of apoptosis
using Hoechst 33285 dye staining as
described in Materials and
Methods, and genomic DNA was extracted and
electrophoresed. Both
H
2O
2 and etoposide
induced DNA laddering (Fig.
1B) and increased
apoptotic-cell number
(Fig.
1C), while the presence of 14,15-EET
markedly reduced the
number of apoptotic cells and eliminated
DNA laddering induced by
either
maneuver.
Cytoprotective effects of endogenously produced 14,15-EET.
Synthetic eicosanoids have been widely utilized for the experimental
analysis of their cellular and organ functions. However, in many cases,
this approach provides only limited information with regard to their
mechanisms of action and the enzymatic steps responsible for their
biosynthesis from endogenous precursors, activation and disposition.
This is of special relevance regarding P450-derived eicosanoids, since
in most cultured cells, there is a rapid and progressive decrease in
the expression of the P450 isoforms found in vivo. Therefore, to
determine the effect of endogenously produced 14,15-EET on epithelial
cell survival, we utilized a LLCPKcl4 cell line transfected with an
engineered epoxygenase of bacterial origin, F87V BM3. This enzyme
converts arachidonic acid selectively (>98% of total products) to
14S,15R-EET, the enantiomer that predominates in
vivo in the kidney (18, 28, 36). Previous studies have
shown that addition of exogenous arachidonic acid to BM3 cells
increased endogenous 14,15-EET levels more than 100-fold, while there
was no measurable increase in Vector cells (18).
Accordingly, quiescent BM3 cells and Vector cells were pretreated with
or without arachidonic acid (10 µM) for 1 h before exposure to
H2O2 for 24 h. In BM3 cells, arachidonic acid
significantly inhibited H2O2-induced DNA
laddering; in contrast, in Vector cells, arachidonic acid not only did
not prevent H2O2-induced DNA laddering but
actually augmented DNA laddering and increased apoptotic-cell number,
compared to treatment with H2O2 alone (Fig. 2).
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FIG. 2.
Effects of endogenously produced 14,15-EET in LLCPKcl4
cells. Arachidonic acid blocked H2O2-induced
apoptosis in BM3 cells but not in Vector cells. Quiescent BM3 cells and
Vector cells were pretreated with or without arachidonic acid (10 µM)
for 1 h before exposure to H2O2 for
24 h, and DNA laddering (A) and apoptotic cell number (B) were
assessed as described in Materials and Methods. (A) Leftmost lane,
100-bp DNA ladder; rightmost lane, lambda DNA-HindIII
DNA size marker.
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14,15-EET activates a PI-3 kinase-Akt-signaling pathway.
We
have previously reported that in quiescent nontransfected LLCPKcl4
cells, 14,15-EET administration activated the mitogen-activated protein
(MAP) kinases p44/p42 extracellular signal-regulated kinases (ERKs) and
phosphatidylinositol-3 kinase (PI-3 kinase) (17), while
arachidonic acid addition activated ERKs and PI-3 kinase in BM3 cells
but not in Vector cells (18), indicating that 14,15-EET can activate both MAP kinase and PI-3 kinase pathways. To determine if
these pathways were involved in mediating the antiapoptotic effects of
14,15-EET, the specific MAP kinase kinase (MEK) inhibitor PD98059 and
two mechanistically and structurally distinct PI-3 kinase inhibitors,
wortmannin and LY294002, were employed. Inhibition of
H2O2-induced DNA laddering (Fig.
3A) and apoptotic cell number (data not
shown) by 14,15-EET was abolished by wortmannin and LY294002 but not by
PD98059. In addition, H2O2-induced
apoptotic body formation, detected by Hoechst 33258, was also abolished by wortmannin or LY294002 but not by PD98059 (data not shown). Determination of FITC-labeled annexin V binding further confirmed the
involvement of PI-3 kinase, but not MAP kinase, in the antiapoptotic effects of 14,15-EET, because 14,15-EET inhibition of
H2O2-induced annexin V binding was abolished by
wortmannin but not by PD98059 (data not shown). In the BM3 cells,
wortmannin and LY294002, but not PD98059, abolished arachidonic
acid-mediated inhibition of DNA laddering (Fig. 3B) and apoptotic-cell
number (data not shown) induced by hydrogen peroxide, indicating
that endogenously produced 14,15-EET exerts antiapoptotic
effects as well. As demonstrated in Fig. 3C, 14,15-EET significantly
increased Akt kinase activity, which was completely blocked by
wortmannin or LY294002.
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FIG. 3.
14,15-EET exerts its antiapoptotic effects in LLCPKcl4
cells by activation of a PI-3 kinase-Akt-signaling pathway. (A)
14,15-EET's antiapoptotic effects were abolished by inhibition of PI-3
kinase but not by inhibition of MAP kinase. After pretreatment with or
without the specific PI-3 kinase inhibitor wortmannin (10 nM) or
LY294002 (5 µM) or the MEK inhibitor PD98059 (10 µM) for 30 min,
followed by 14,15-EET or vehicle for 1 h, LLCPKcl4 cells were
exposed to H2O2 for 24 h, and DNA
laddering was assessed. (B) Arachidonic acid's antiapoptotic effects
in BM3 cells were abolished by inhibition of PI-3 kinase but not by
inhibition of MAP kinase. Before induction of
H2O2-mediated apoptosis, BM3 cells were
pretreated with or without wortmannin, LY294002, or PD98059 and then
treated with or without arachidonic acid. (A and B) Leftmost lane,
100-bp DNA ladder; rightmost lane, lambda DNA-HindIII
size marker. (C) 14,15-EET increased Akt kinase activity, which was
abolished by either wortmannin or LY294002. After treatment with or
without the specific PI-3 kinase inhibitor wortmannin (10 nM) or
LY294002 (5 µM), LLCPKcl4 cells were treated with or without
14,15-EET. The cells were then lysed and subjected to
immunoprecipitation and Akt kinase activity assay with histone H2B as a
substrate.
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Arachidonic acid-induced apoptosis.
Hydrogen peroxide has been
reported to activate phospholipase A2 (PLA2)
and release arachidonic acid (8, 14). To investigate further the observation that arachidonic acid administration augmented H2O2-induced apoptosis in LLCPKcl4 cells (Fig.
2A), quiescent BM3 cells and Vector cells were treated with or without
arachidonic acid (10 µM) for 48 h in the absence of other
apoptosis-inducing stimuli. Arachidonic acid induced apoptotic cell
death in Vector cells but not in BM3 cells, as indicated by DNA
laddering (Fig. 4) and apoptotic cell
counts (data not shown).
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FIG. 4.
Arachidonic acid induced apoptosis in Vector cells but
not in BM3 cells. Quiescent BM3 cells and Vector cells were treated
with or without arachidonic acid (10 µM) for 48 h in the absence
of other apoptosis-inducing stimuli and then subjected to assessment of
DNA laddering. Leftmost lane, 100-bp DNA ladder; rightmost lane, lambda
DNA-HindIII size marker.
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Ceramide mediates arachidonic acid-induced apoptosis.
Administration of arachidonic acid to the nontransfected LLCPKcl4
cells induced ceramide production within 1 h that remained elevated for up to 48 h, the longest time tested (Fig.
5A). In contrast, arachidonic acid
addition did not increase ceramide levels in BM3 cells, although it
significantly increased ceramide levels in Vector cells (Fig. 5B),
similar to its effect in the wild-type cells. In BM3 cells pretreated
with the P450 inhibitor 17-octadecynoic acid, previously shown
to inhibit BM3 epoxygenase activity (18, 51),
administration of arachidonic acid increased ceramide levels (Fig. 5C)
and induced apoptosis (Fig. 5D). Direct administration of the
cell-permeable C2-ceramide (25 µM) induced apoptosis in quiescent
Vector cells and BM3 cells, while pretreatment of Vector cells with
14,15-EET or BM3 cells with arachidonic acid decreased the extent of
apoptosis (Fig. 5E).
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FIG. 5.
Ceramide mediates arachidonic acid-induced apoptosis.
(A) Time course of arachidonic acid induced-ceramide generation in
LLCPKcl4 cells. Quiescent cells were treated with or without
arachidonic acid (10 µM) for the indicated times, the cells were then
harvested, and ceramide levels were quantitated as described in
Materials and Methods. (B) Arachidonic acid increased ceramide
generation in Vector cells but not in BM3 cells. Vector cells and BM3
cells were rendered quiescent and treated with or without arachidonic
acid (10 µM) for 48 h. Ceramide levels were determined as
described in Materials and Methods. (C and D) Arachidonic acid
increased ceramide levels and induced apoptosis in BM3 cells pretreated
with a P450 inhibitor. Quiescent BM3 cells were pretreated with or
without the P450 inhibitor 17-ODYA (20 µM) and treated with or
without arachidonic acid (10 µM). The cells were then harvested and
ceramide levels were measured (C), and apoptosis was determined (D).
(E) 14,15-EET and arachidonic acid inhibited apoptosis induced by
administration of ceramide in Vector cells and BM3 cells, respectively.
Vector cells and BM3 cells were made quiescent and pretreated with or
without 14,15-EET (Vector cells) or arachidonic acid (BM3 cells); they
were then exposed to the cell-permeable C2-ceramide (25 µM), and
apoptosis was assessed. (D and E) Leftmost lane, 100-bp DNA ladder;
rightmost lane, 1-kb DNA ladder.
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Arachidonic acid induces apoptosis by activating the neutral
sphingomyelinase pathway.
Pretreatment of LLCPKcl4 cells with the
ceramide synthase inhibitor fumonisin B1 did not affect arachidonic
acid-induced ceramide elevation (Fig. 6A)
and had no effect on arachidonic acid-induced apoptosis (Fig. 6B); in
contrast, the neutral sphingomyelinase inhibitor scyphostatin
(42, 43) blocked arachidonic acid-induced ceramide
production (Fig. 6C) and abolished arachidonic acid-induced apoptosis
as well (Fig. 6D). Interestingly, the pan-caspase inhibitor Z-VAD-fmk
had no effect on arachidonic acid-induced ceramide generation (Fig. 6A)
but significantly inhibited arachidonic acid-induced apoptosis (Fig.
6B), indicating that caspases are downstream effectors of ceramide in
the arachidonic acid-activated apoptotic signaling pathway.
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FIG. 6.
Arachidonic acid induces apoptosis by activating neutral
sphingomyelinase pathway. (A and B) Effects of ceramide synthase
inhibitor and caspase inhibitor on arachidonic acid-induced ceramide
production and apoptosis in LLCPKcl4 cells. Quiescent cells were
pretreated with vehicle, fumonisin B1 (50 µM), or Z-VAD-fmk (50 µM)
for 1 h, followed by treatment with or without arachidonic acid
(10 µM). Cells were then harvested, ceramide levels were measured
1 h after administration of arachidonic acid (A), and apoptosis
was determined 24 h after administration of arachidonic acid (B).
(C and D) Effects of the neutral sphingomyelinase inhibitor
scyphostatin on arachidonic acid-induced ceramide production and
apoptosis in LLCPKcl4 cells. Quiescent cells were pretreated with or
without scyphostatin (1 µM) for 1 h followed by treatment with or
without arachidonic acid (10 µM). Cells were then harvested, ceramide
levels were measured (C), and apoptosis was determined (D). (B and D)
Leftmost lane, 100-bp DNA ladder; rightmost lane, 1-kb DNA ladder.
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DISCUSSION |
To date, three enzymatic pathways of arachidonic acid
metabolism, cyclooxygenase, lipoxygenase, and cytochrome P450 enzymes, have been identified in mammalian systems. Cyclooxygenase- and lipoxygenase-mediated arachidonic acid metabolic pathways have been
extensively characterized, and their contributions to pathophysiology have been well established, including potential roles in epithelial cancers, such as colon, breast, and prostate carcinoma (2, 25,
44; R. A. Gupta and R. N. DuBois, Editorial,
Gastroenterology 114:1095-1098, 1998). There is increasing
interest in cyclooxygenase and lipoxygenase inhibitors as
cancer-preventive agents, since these inhibitors are known to induce
apoptosis (2, 35, 50). However, it remains to be
determined which arachidonic acid metabolites produced by these
pathways are involved in preventing apoptosis and/or how arachidonic
acid itself induces apoptosis. In this regard, it has been suggested
that cyclooxygenase and lipoxygenase inhibitors may be cancer
preventive not only by inhibiting production of specific antiapoptotic
arachidonic acid metabolites but also by preventing metabolism of free
arachidonic acid, which promotes neutral sphingomyelinase activity and
increases production of the proapoptotic lipid ceramide (15,
54). Utilizing human epithelial cell lines with stable,
inducible expression of cyclooxygenase-2 and/or fatty acid-coenzyme A
ligase 4, a recent study has shown that free arachidonic acid is a
critical signal for apoptosis and that the induction of apoptosis by
nonsteroidal anti-inflammatory drugs, the fatty acid-coenzyme A ligase
inhibitor triacsin C, and other cyclooxygenase and lipoxygenase
inhibitors of arachidonic acid metabolism is a consequence of an
accumulation of intracellular free arachidonic acid (9).
In contrast, much less attention has been paid to the cytochrome P450
monooxygenase pathway, the third major pathway of arachidonic acid metabolism.
The cytochrome P450 hemoproteins represent the most abundant and widely
distributed group of eukaryotic monooxygenases. In mammals, these
proteins are expressed in almost all cell types, but despite
delineation of their biochemical and biophysical properties and
extensive insight into roles in toxicology and pharmacology, little is
known about their physiologic roles in nonsteroidogenic organs. The
demonstration that arachidonic acid is an endogenous substrate for
cytochrome P450 has stimulated investigations of biologic roles for
these metabolites. EETs have been proposed to act as second messengers
for hormones and growth factors. In this regard, we have demonstrated
that EETs serve as second messengers for epidermal growth factor in
renal epithelial cells (6, 18) and are potent
mitogens via activation of a Src kinase-mediated tyrosine kinase
cascade (16, 17). The present studies document an
additional novel role for 14,15-EET to inhibit apoptosis induced by
such diverse proapoptotic stimuli as H2O2,
etoposide, and excess arachidonic acid. These antiapoptotic effects
were observed either with exogenous addition of 14,15-EET or following
transfection of the biosynthetic machinery necessary for its endogenous
biosynthesis from arachidonic acid, thus establishing a clear
cause-and-effect relationship between the cytochrome P450 epoxygenase
pathway and its metabolite, 14,15-EET. Furthermore, we also show that a
single chemical entity, 14,15-EET, can replace the serum requirements for LLCPKcl4 cells and support cell viability. An additional
cytoprotective role of P450 epoxygenase is to metabolize and
thereby prevent accumulation of toxic levels of free arachidonic acid.
PI-3 kinase, composed of an 85-kDa regulatory subunit and a 110-kDa
catalytic subunit, is activated by a wide range of cytokines, hormones,
and growth factors (24, 55). PI-3 kinases and their phospholipid products, PI-3,4,5-trisphosphate
[PI(3,4,5)P3] and PI(3,4)P2, have been demonstrated to
promote growth factor-mediated cell survival and to prevent apoptosis
in many cell types (47, 61). Our present studies show that
although 14,15-EET activates both PI-3 kinase and ERKs, it is
activation of PI-3 kinase that is essential for the antiapoptotic
signaling pathway of 14,15-EET. It has previously been shown that the
ubiquitously expressed serine/threonine protein kinase B, also called
Akt, is the downstream target of PI-3 kinase in the growth
factor-mediated cytoprotective signaling pathways (5, 23).
In the present studies, 14,15-EET also significantly increased Akt
activity, suggesting that 14,15-EET exerts its potent antiapoptotic
effects through activation of a PI-3 kinase-Akt-signaling pathway.
The second lipid messenger, ceramide, regulates cellular
differentiation, proliferation, and apoptosis in both stimulus- and cell-type-specific fashions. Very often, however, the outcome of
ceramide-mediated signaling is apoptosis, and increasing evidence suggests that the sphingomyelin-signaling system is an upstream signaling mechanism that links cell surface receptors and environmental stresses to the apoptotic pathway (37). Although the
mechanisms of ceramide-induced apoptosis are still incompletely
understood, in the past years the c-Jun N-terminal kinase and
p38 MAP kinase pathways have been linked to the ceramide-initiated
apoptosis (30, 58). Interestingly, ceramide has recently
been shown to induce apoptosis by dephosphorylation of Akt at residues
Thr-308 and Ser-473 through a ceramide-activated protein phosphatase, thus inhibiting Akt activity (48). Akt has also been shown
to prevent formation of ceramide in response to proapoptotic stimuli and protect cells against ceramide-induced apoptosis (27).
The potent cytotoxic effect of tumor necrosis factor alpha has been shown to signal through activation of the cytosolic PLA2
(cPLA2) and release of free arachidonic acid, which acts as
an essential precursor for tumor necrosis factor alpha to induce
activation of the sphingomyelin-signaling cycle and, as a result,
formation of the proapoptotic ceramide (34). In the
present study, we showed that ceramide is a potent inducer of apoptosis
for renal epithelial cells and that ceramide is an effector of
arachidonic acid-mediated apoptosis. We demonstrate that cells that
lack functional cytochrome P450 activity as well as cyclooxygenase and
lipoxygenase are susceptible to apoptosis when exposed to free
arachidonic acid. In contrast, introduction of enzymatically active
P450 epoxygenase into these cells restored their arachidonic acid
metabolic function and prevented arachidonic acid-induced ceramide
production, and thereby provided these cells with resistance to free
arachidonic acid-induced apoptosis.
Since the ceramide synthase inhibitor had no inhibitory effect on
ceramide elevation and apoptosis induced by arachidonic acid, these
effects are likely not due to activation of ceramide synthase and
initiation of de novo synthesis of ceramide. The blockade of these
effects of arachidonic acid by a neutral sphingomyelinase inhibitor
provides direct evidence that unesterified arachidonic acid induces
apoptosis through activation of the neutral sphingomyelinase pathway,
resulting in conversion of sphingomyelin to ceramide. The pan-caspase
inhibitor had no effect on arachidonic acid-induced ceramide generation
but did inhibit arachidonic acid-induced apoptosis, suggesting that
ceramide is upstream of caspases in the arachidonic acid-activated
apoptotic pathway, as schematized in Fig.
7.
View larger version (24K):
[in this window]
[in a new window]
|
FIG. 7.
Arachidonic acid-ceramide-apoptosis-signaling pathway is
regulated by cytochrome P450 in LLCPKcl4 cells. Arachidonic acid, an
important constituent of cell membrane, is released by activation of
specific phospholipases (PLA2) and further metabolized by
cyclooxygenases, lipoxygenases, and cytochrome P450 pathways. If
unesterified arachidonic acid is not metabolized, it activates neutral
sphingomyelinase (N-SMase), which converts sphingomyelin to the second
messenger, ceramide. Ceramide induces caspase activation, which leads
to apoptosis. In cells such as the renal proximal tubule, in which
cyclooxygenase and lipoxygenase are expressed at nearly undetectable
levels, arachidonic acid metabolism is shunted to the cytochrome P450
pathway. This metabolism not only metabolizes and detoxifies excess
unesterified arachidonic acid to prevent proapoptotic ceramide
formation but also produces a metabolite, 14,15-EET, which activates a
PI-3 kinase-Akt-signaling pathway. Thus, cytochrome P450 mediates cell
survival by two complementary mechanisms.
|
|
Moreover, the active P450 epoxygenase introduced into these cells had
been engineered to metabolize arachidonic acid only to 14,15-EET, which
renders the cells resistant to apoptosis-inducing agents such as
hydrogen peroxide in addition to arachidonic acid per se. Thus, in
addition to the production of the antiapoptotic lipid 14,15-EET, our
present studies also show that metabolism of free arachidonic acid by
P450 prevents free arachidonic acid-mediated ceramide formation.
Therefore, P450 serves as an important regulator of cell survival by
decreasing proapoptotic signals as well as by increasing antiapoptotic
signals, as illustrated in Fig. 7.
In summary, the present results demonstrate that cytochrome P450
epoxygenase prevents apoptosis by two complementary mechanisms. This
enzyme both metabolizes and detoxifies excess free arachidonic acid to
prevent proapoptotic ceramide production and also produces a
metabolite, 14,15-EET, that is a potent inhibitor of apoptosis by
activation of a PI-3 kinase-Akt-signaling pathway. These studies elucidate a new functional role for the P450 epoxygenase pathway of
arachidonic acid metabolism and shed new light on the mechanisms by
which unesterified arachidonic acid signals apoptosis.
| |
ACKNOWLEDGMENTS |
We thank Takeshi Ogita (Sankyo Co. Ltd., Tokyo, Japan) for his
generous provision of the newly described neutral sphingomyelinase inhibitor scyphostatin.
This work was supported by National Institutes of Health grant DK38226
(R.C.H., J.C., and J.R.F.) and funds from the Department of Veterans
Affairs (R.C.H.).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Division of
Nephrology, S 3322, MCN, Vanderbilt University School of Medicine,
Nashville, TN 37232. Phone: (615) 343-0030. Fax: (615) 343-7156. E-mail: Ray.Harris{at}mcmail.vanderbilt.edu.
| |
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Molecular and Cellular Biology, September 2001, p. 6322-6331, Vol. 21, No. 18
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.18.6322-6331.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
