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Cyclosporin a inhibits biological effects of tumor promoting phorbol esters
Vol. 126, No. 1, 1965
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS Pages 327-332
January 16, 1965
CYCLOSPORIN A INHIBITS
BIOLOGICAL
M. Gschwendt,
EFFECTS OF TUMOR PROMOTING PHORBOL ESTERS
W. Kittstein,
F. Horn,
and F. Marks
Deutsches Krebsforschungszentrum, Institut fiir Im Neuenheimer Feld 280, D-6900 Heidelberg, Received
November
Biochemie, F.R.G.
26, 1984
The antilymphocytic and antiphlogistic agent cyclosporin A (CsA) inhibits in vivo various effects induced by the tumor promoting phorbol ester 12-O-tetXZf&anoylphorbol-13-acetate (TPA). These include the edema of the mouse ear, the alkaline phosphatase (AP) activity and the ornithine decarboxylase (ODC) activity in mouse epidermis as well as the generation of a specific arachidonic acid (AA) metabolite in mouse epidermis. AA metabolism in an epidermal cell-free system of mouse epidermis was not suppressed by CsA. According to thin layer chromatography the TPA-induced and as yet unidentified AA metabolite exhibits a polarity between that of 5-HETE and 12-/15-HETE. Studies with inhibitors indicate it to be a lipoxygenase product. 0 1985 Academic Press, Inc.
CsA is biology
for
the
the
production
of this
inhibitory
the
phospholipid property
whether
this
activity
whether
both
activities
pound.
Very
activation
metabolism
further
of CsA is
recently
of prostaglandins
to these known.
its
lymphocyte
antiphlogistic
of CsA is
related
are entirely it
the
to inhi-
(3-5).
activity
(1).
CsA recep-
properites
that changes
(7). It
in
A
is not known
antilymphocytic
be due to an inhibition
The mode
the early membrane
suppression
as to
was reported
plasma
independent
was shown that
by CsA might
with
to its
most
ability
however,
and it
by interfering
of the
The immuno-
Probably
lymphokines
(6)
(1).
1 and 2, as well
Recently,
on human lymphocytes
lymphocyte
(2).
of CsA is its
interleukin
e.g.
is not yet
activity
by Thomson
capacity
of T cells
action
demonstrated
CsA inhibits
recently
of lymphokines,
the responsiveness
were
antilymphocytic
immunosuppressive
inhibit
tors
with
of CsA has been reviewed
important bit
an immune suppressant
activity of the
of tissue
or
com-
levels
of phospholipase
A2 (8). Tumor sumably
promotion from
is a single
a complex cell
process that
in which
has been
327
a visible
initiated
tumor
develops
by a carcinogen.
pre-
The
0006-291X/85 $1.50 Copyright 0 I985 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol. 126, No. 1, 1985
most bol
thoroughly esters
effects
studied
esters
of tumor
elucidation
generation other
in this (9).
of phorbol
mechanism.
of an AA metabolite
effects
of tumor
a still
esters
increasing
Inhibitors should
Here we report
phorbol
MATERIAL
promotion
by phornumber
has been described,
as yet.
and on the
promoting
is tumor
and --in vitro
is unknown
effects
of this
respect
Although
--in vivo
promotion
and of various
the
system
in mouse epidermis
of phorbol
mechanism tion
BlOCHEMlCALANDBlOPHYSlCALRESEARCHCOMMUNlCATlONS
promo-
tools
for
on the TPA-induced
inhibition esters
the
of tumor
be valuable
of
by CsA of this on mouse epidermis
and --in vivo.
AND METHODS
Materials:
doz, Basel, Switzerland. German Cancer Research Animals:
Female
NMRI mice
Edema induction Alkaline Ornithine
7 to 8 weeks)
and measurement:
as described
previously
(10).
as described
previously
(11).
(AP)
decarboxylase
assay:
(ODC) assay:
of protein: and analysis
were
Dr.
(age
phosphatase
Determination Generation
TPA was kindly supplied by Prof. Center, Heidelberg, F.R.G.
as described
was carried
out
of arachidonic
according
acid
used in all
by O'Brien to Lowry
E. Hecker, experiments.
et al.
(12).
et al.
(13).
(AA) metabolites:
Epidermal specimens were prepared from frozen back skin of mice and homogenized as described previously (11). The homogenate was centrifuged at 8,000 x g for 1 min. One ml of the supernatant (epidermal cell-fre system; 800 pg protein/ml) was incubated with 10 pl of a 1:l mixture of [I&]AA and unlabeled AA at 370C for 45 min. After cooling in ice, 3 ml of chloroform/ methanol (19:l) were added. After extensive mixing, the phases were separated by centrifugation at 10,000 x g for 5 min. 2.5 ml of the chloroform/methanol phase were evaporated to dryness and redissolved in 30 pl chloroform/methanol (2:l). A 25 pl aliquot was analyzed by thin layer chromatograph on silica 60 (Merck/Darmstadt) using ether/hexane/acetic acid (60:40:1 7 as developing solvent. The chromatographic analysis was recorded by a radiochromatogram scanner (Berthold). RESULTS AND DISCUSSION The inhibition The edema of the
of various mouse ear,
TPA effects which
in vivo
was found
328
by CsA is
to be maximal
shown in 6 h after
Table the
1.
Vol.
126,
BlOCHEMlCALANDBlOPHYSlCALRESEARCHCOMMUNlCATlONS
No. 1, 1985
Table
1:Inhibition
of
various
TPA-effect
Edema
TPA effects
Dose
(mouse
ear)a
of
by CsA in
CsA
Inhibition
25
(mouse
ODC activity
acid (mouse
A single
dose
of
::
skin)b
(mouse
Arachidonic metabolite
(%)
31 75
La 50 w 100 IN 250 u9 AP activity
vivo
1.5 2.5
mg mg
60 100
2.0
mg
92
2.5
mg
100
skin)c
skin)d
CsA,
as
indicated,
was
applied
together
with
a The edema was measured 6 h after TPA treatment. Each mean of 4 determinations. With 1 nmole TPA alone the ear plug increased from 10.45 to 21.54 mg (difference: 0% inhibition). For the procedure see ref. 10.
TPA.
value is the weight of the 11.09 mg =
b AP activity was measured 22 h after TPA treatment. Each value is the mean of 6 determinations. With 20 nmole TPA alone the absorbance at 405 nm increased from 0.77 to 8.80/mg protein (difference: 8.03/mg protein = 0% inhibition). For the procedure see ref. 11. '
ODC activity was measured mean of 2 determinations. increased from 80 to 4537 For the procedure see ref.
d
see
Figure
application
our
1
of 1 nmole TPA (lo),
CsA. Besides activity
the
recent
tested
back
of
20 nmole
mice.
of skin
all
tumor
CsA. The other
Because
of
the
been
promotion
effects
larger
single
treatment
effect
was
mouse
completely
epidermis
of the
skin abolished
was
with
area
increased
tumor if
2.5
329
90% by 100 pg of
demonstrated
inhibitors
of TPA and up to 2.5 mg of CsA were
in
AP activity
with
that
to about
of CsA, an antiphlogistic
has already
we proposed
inhibitors
presently
properties
inflammation
findings,
edema are also
was suppressed
immunosuppressive
in chronic
skin
4 h after TPA treatment. The value is the With 20 nmole TPA alone the radioactivity cpm (difference: 4457 cpm = 0% inhibition). 12.
used. more
promoting mg CsA
of the TPA-induced This
(10).
of TPA were for
were
Based on
(1).
the
hypothesis
determined
in the
topical
application,
Recently,
we found
than
phorbol applied
lo-fold
22
esters together
is
that
h after
a
This
(11). with
Vol. 126,No.
1, 1985
TPA. As discussed induced that
capillary
several
by TPA.
resistance.
If
wellknown
was also
suppressed
the TPA-induced vivo
(Fig.
layer
TPA effect,
this
holds
To our
the
1 and Table
chromatography
indicated
from
that
leaking
true,
knowledge,
increase
CsA should however,
in epidermal
by CsA. Finally, of an AA metabolite
l).The
as yet
unidentified
between
5- and 12-/15-HETE
the TPA-
endothelial be able
cells to
a stabilizing
has not been described
very efficiently generation
data
arose
of CsA on the microvasculature
Another
thin
(ll),
in mouse epidermis
had been damaged
effect
in
previously
AP activity
increase
tely
BlOCHEMlCALANDBlOPHYSlCALRESEARCHCOMMUNlCATlONS
as yet.
ODC activity CsA inhibited
(12), comple-
in mouse epidermis metabolite (Figure
migrated 1). To our
I
TPA
TPAlCsA
Figure mis in
1: Radiochromatogram vitro.
of
AA metabolites
generated
in
mouse
epider-
Two hundred pl acetone alone (control), 20 nmole TPA in acetone or 20 nmole TPA/2.5 mg CsA in acetone were applied to the shaved back skin of 2 mice each. 24 hours later the mice were sacrificed. Epidermal specimens were prepared from the back skin, homogenized and used for the generation of AA metabolites in vitro as described in Methods. Extraction of metabolites, separation by thin layer chromatography and analysis of the radiochromatogram were performed as described in Methods. [3H]-5-HETE, [3H]-12-HETE and [3H]-15-HETE served as standards. The profiles were reproduced in 5 independent experiments.
330
on
Vol. 126,No.
1, 1985
BlOCHEMlCALANDBlOPHYSlCALRESEARCHCOMMUNlCATlONS
the
by TPA of such a metabolite
knowledge previously. lite not
induction
Lysed
in vitro, shown).
invading that
the epidermis
system.
by the
but
This
secondly,
in tumor
cell-free
system
promotion
(14),
Recently,
by directly
is
however,
an indirect
possible
that
by CsA in vivo.
immunosuppressive effects.
One possibility
leading CsA. CsA is
agent
to these It
remains based
also
various
Taken
CsA is is
that
effects
an open question on the
inhibition
to play
a very potent there
cell-free
respect
whether
the
of this 331
even at in vivo
Furthermore,
it
is
of PKC by TPA was results
inhibitor
this
of the
does not exclude,
indicate
process
unknown
the
TPA process
can be inhibited
immunosuppressive as yet
that
of several
is a common TPA-induced
and that
epidermal
the TPA effects
stimulation the
a central
a 50% inhibition
PKC. This
together,
pathway
of PKC by TPA
in this
CsA inhibited
the
metabolite
by CsA in the
caused
not
inhibitor.
in an epidermal
phloretin
(data
cyclooxygenase
of PKC by CsA in vivo.
following
howacid
the TPA-induced
on the stimulation
TPA-stimulated
inhibition
completely,
is thought
CsA was ineffective
the
a process
which
inhibitors
that
the
indomethacin
the
it
cell-
including
as a lipoxygenase
was not suppressed
not likely
inhibiting
than
act
C (PKC),
2x10e5M
PKC-activity. it
simply
by various
system
epidermal
nordihydroguaiaretic
that
rather
we reported
For instance,
Thus
suppressed
not
kinase
TPA-stimulated 5x10m4M.
CsA did
suppression
(15).
lipoxygenase
exclude
and that
in the
inhibitor
place
we cannot
such "TPA-activated"
quercetin,
first
leucocytes
with
was suppressed
cyclooxygenase
protein
system.
and on its
the
that
TPA-stimulated
metabolite
(data
metabolite
of AA in this
in the
metabo-
this
metabolism
not by the
along
to produce
inhibitors
indicates
was generated
Nevertheless,
AA metabolism
lipoxygenase
this
by "ordinary"
to inhibit
TPA-induced
not produce
generated
due to a contamination
The in vitro of the
was not
did
AA to HETEs efficiently
TPA treatment.
CsA was unable
and sesamol,
role
metabolized
leucocytes
in our assay
generation
and,
after
TPA caused
leucocytes.
shown).
they
Thus the metabolite
was found
ever,
from mouse blood
even though
in vivo
free
leucocytes
has not been reported
activity process.
by of
Vol. 126, No. 1, 1985
BIOCHEMICALAND
BIOPHYSICALRESEARCH
COMMUNICATIONS
ACKNOWLEDGEMENT We are
very
grateful
to Sandoz,
Basel,
for
the
gift
of cyclosporin
A.
REFERENCES 1
34 5 6
9 10 11 12 13 14 15
Borel, J.F., Feuerer C., Gubler, H.U., and Stahelin, H. (1976) Agents actions 6, 468-475. Thomson, A.W. (1983) Aust. J. Exp. Biol. Med. Sci. 61, 147-172. Larsson, E.-L. (1980) J. Immunol. 124, 2828-2833. Bunjes, D., Hardt, C., Rollinghoff, M., and Wagner, H. (1981) Eur. J. Immunol. 11, 657-661. Hess, A.D., Tutschka, P.J., Pu, Z., and Santos, G.W. (1982) J. Immunol. 128, 360-367. Ryffel, B., Gdtz, U., and Heuberger, B. (1982) J. Immunol. 129, 19781982. Szamel, M., Berger, P., and Resch, K. (1984) Immunobiology 167, 208. Fan, T.-P.D. and Lewis, G.P. (1984) IUPHAR 9th International Congress of Pharmacology, London. Hecker, E., Fusenig, N:E., Kunz, W., Marks, F., and Thielmann, H.W. (eds.) (1982) Carcinogenesis, Vol. 7, Raven Press, New York. Gschwendt, M., Kittstein, W., FUrstenberger, G., and Marks, F. (1984) Cancer Letters, in press. Gschwendt, M., Kittstein, W., and Marks, F. (1984) Cancer Letters 22, 219-225. O'Brien, T.G., Simsiman,,R.C., and Boutwell, R.K. (1975) Cancer Res. 35, 1662-1670. N.J., Farr, A.L., and Randall, J.R. (1951) Lowry, O.H., Rosebrough, J. Biol. Chem. 193, 265-275. Nishizuka, Y. (1984) Nature (London) 308, 693-698. Gschwendt, M., Horn, F., Kittstein, W., FUrstenberger, G., Besemfelder, E 0, and Marks, F. (1984) Biochem. Biophys. Res. Commun. 124, 63-68.
332
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS Pages 327-332
January 16, 1965
CYCLOSPORIN A INHIBITS
BIOLOGICAL
M. Gschwendt,
EFFECTS OF TUMOR PROMOTING PHORBOL ESTERS
W. Kittstein,
F. Horn,
and F. Marks
Deutsches Krebsforschungszentrum, Institut fiir Im Neuenheimer Feld 280, D-6900 Heidelberg, Received
November
Biochemie, F.R.G.
26, 1984
The antilymphocytic and antiphlogistic agent cyclosporin A (CsA) inhibits in vivo various effects induced by the tumor promoting phorbol ester 12-O-tetXZf&anoylphorbol-13-acetate (TPA). These include the edema of the mouse ear, the alkaline phosphatase (AP) activity and the ornithine decarboxylase (ODC) activity in mouse epidermis as well as the generation of a specific arachidonic acid (AA) metabolite in mouse epidermis. AA metabolism in an epidermal cell-free system of mouse epidermis was not suppressed by CsA. According to thin layer chromatography the TPA-induced and as yet unidentified AA metabolite exhibits a polarity between that of 5-HETE and 12-/15-HETE. Studies with inhibitors indicate it to be a lipoxygenase product. 0 1985 Academic Press, Inc.
CsA is biology
for
the
the
production
of this
inhibitory
the
phospholipid property
whether
this
activity
whether
both
activities
pound.
Very
activation
metabolism
further
of CsA is
recently
of prostaglandins
to these known.
its
lymphocyte
antiphlogistic
of CsA is
related
are entirely it
the
to inhi-
(3-5).
activity
(1).
CsA recep-
properites
that changes
(7). It
in
A
is not known
antilymphocytic
be due to an inhibition
The mode
the early membrane
suppression
as to
was reported
plasma
independent
was shown that
by CsA might
with
to its
most
ability
however,
and it
by interfering
of the
The immuno-
Probably
lymphokines
(6)
(1).
1 and 2, as well
Recently,
on human lymphocytes
lymphocyte
(2).
of CsA is its
interleukin
e.g.
is not yet
activity
by Thomson
capacity
of T cells
action
demonstrated
CsA inhibits
recently
of lymphokines,
the responsiveness
were
antilymphocytic
immunosuppressive
inhibit
tors
with
of CsA has been reviewed
important bit
an immune suppressant
activity of the
of tissue
or
com-
levels
of phospholipase
A2 (8). Tumor sumably
promotion from
is a single
a complex cell
process that
in which
has been
327
a visible
initiated
tumor
develops
by a carcinogen.
pre-
The
0006-291X/85 $1.50 Copyright 0 I985 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol. 126, No. 1, 1985
most bol
thoroughly esters
effects
studied
esters
of tumor
elucidation
generation other
in this (9).
of phorbol
mechanism.
of an AA metabolite
effects
of tumor
a still
esters
increasing
Inhibitors should
Here we report
phorbol
MATERIAL
promotion
by phornumber
has been described,
as yet.
and on the
promoting
is tumor
and --in vitro
is unknown
effects
of this
respect
Although
--in vivo
promotion
and of various
the
system
in mouse epidermis
of phorbol
mechanism tion
BlOCHEMlCALANDBlOPHYSlCALRESEARCHCOMMUNlCATlONS
promo-
tools
for
on the TPA-induced
inhibition esters
the
of tumor
be valuable
of
by CsA of this on mouse epidermis
and --in vivo.
AND METHODS
Materials:
doz, Basel, Switzerland. German Cancer Research Animals:
Female
NMRI mice
Edema induction Alkaline Ornithine
7 to 8 weeks)
and measurement:
as described
previously
(10).
as described
previously
(11).
(AP)
decarboxylase
assay:
(ODC) assay:
of protein: and analysis
were
Dr.
(age
phosphatase
Determination Generation
TPA was kindly supplied by Prof. Center, Heidelberg, F.R.G.
as described
was carried
out
of arachidonic
according
acid
used in all
by O'Brien to Lowry
E. Hecker, experiments.
et al.
(12).
et al.
(13).
(AA) metabolites:
Epidermal specimens were prepared from frozen back skin of mice and homogenized as described previously (11). The homogenate was centrifuged at 8,000 x g for 1 min. One ml of the supernatant (epidermal cell-fre system; 800 pg protein/ml) was incubated with 10 pl of a 1:l mixture of [I&]AA and unlabeled AA at 370C for 45 min. After cooling in ice, 3 ml of chloroform/ methanol (19:l) were added. After extensive mixing, the phases were separated by centrifugation at 10,000 x g for 5 min. 2.5 ml of the chloroform/methanol phase were evaporated to dryness and redissolved in 30 pl chloroform/methanol (2:l). A 25 pl aliquot was analyzed by thin layer chromatograph on silica 60 (Merck/Darmstadt) using ether/hexane/acetic acid (60:40:1 7 as developing solvent. The chromatographic analysis was recorded by a radiochromatogram scanner (Berthold). RESULTS AND DISCUSSION The inhibition The edema of the
of various mouse ear,
TPA effects which
in vivo
was found
328
by CsA is
to be maximal
shown in 6 h after
Table the
1.
Vol.
126,
BlOCHEMlCALANDBlOPHYSlCALRESEARCHCOMMUNlCATlONS
No. 1, 1985
Table
1:Inhibition
of
various
TPA-effect
Edema
TPA effects
Dose
(mouse
ear)a
of
by CsA in
CsA
Inhibition
25
(mouse
ODC activity
acid (mouse
A single
dose
of
::
skin)b
(mouse
Arachidonic metabolite
(%)
31 75
La 50 w 100 IN 250 u9 AP activity
vivo
1.5 2.5
mg mg
60 100
2.0
mg
92
2.5
mg
100
skin)c
skin)d
CsA,
as
indicated,
was
applied
together
with
a The edema was measured 6 h after TPA treatment. Each mean of 4 determinations. With 1 nmole TPA alone the ear plug increased from 10.45 to 21.54 mg (difference: 0% inhibition). For the procedure see ref. 10.
TPA.
value is the weight of the 11.09 mg =
b AP activity was measured 22 h after TPA treatment. Each value is the mean of 6 determinations. With 20 nmole TPA alone the absorbance at 405 nm increased from 0.77 to 8.80/mg protein (difference: 8.03/mg protein = 0% inhibition). For the procedure see ref. 11. '
ODC activity was measured mean of 2 determinations. increased from 80 to 4537 For the procedure see ref.
d
see
Figure
application
our
1
of 1 nmole TPA (lo),
CsA. Besides activity
the
recent
tested
back
of
20 nmole
mice.
of skin
all
tumor
CsA. The other
Because
of
the
been
promotion
effects
larger
single
treatment
effect
was
mouse
completely
epidermis
of the
skin abolished
was
with
area
increased
tumor if
2.5
329
90% by 100 pg of
demonstrated
inhibitors
of TPA and up to 2.5 mg of CsA were
in
AP activity
with
that
to about
of CsA, an antiphlogistic
has already
we proposed
inhibitors
presently
properties
inflammation
findings,
edema are also
was suppressed
immunosuppressive
in chronic
skin
4 h after TPA treatment. The value is the With 20 nmole TPA alone the radioactivity cpm (difference: 4457 cpm = 0% inhibition). 12.
used. more
promoting mg CsA
of the TPA-induced This
(10).
of TPA were for
were
Based on
(1).
the
hypothesis
determined
in the
topical
application,
Recently,
we found
than
phorbol applied
lo-fold
22
esters together
is
that
h after
a
This
(11). with
Vol. 126,No.
1, 1985
TPA. As discussed induced that
capillary
several
by TPA.
resistance.
If
wellknown
was also
suppressed
the TPA-induced vivo
(Fig.
layer
TPA effect,
this
holds
To our
the
1 and Table
chromatography
indicated
from
that
leaking
true,
knowledge,
increase
CsA should however,
in epidermal
by CsA. Finally, of an AA metabolite
l).The
as yet
unidentified
between
5- and 12-/15-HETE
the TPA-
endothelial be able
cells to
a stabilizing
has not been described
very efficiently generation
data
arose
of CsA on the microvasculature
Another
thin
(ll),
in mouse epidermis
had been damaged
effect
in
previously
AP activity
increase
tely
BlOCHEMlCALANDBlOPHYSlCALRESEARCHCOMMUNlCATlONS
as yet.
ODC activity CsA inhibited
(12), comple-
in mouse epidermis metabolite (Figure
migrated 1). To our
I
TPA
TPAlCsA
Figure mis in
1: Radiochromatogram vitro.
of
AA metabolites
generated
in
mouse
epider-
Two hundred pl acetone alone (control), 20 nmole TPA in acetone or 20 nmole TPA/2.5 mg CsA in acetone were applied to the shaved back skin of 2 mice each. 24 hours later the mice were sacrificed. Epidermal specimens were prepared from the back skin, homogenized and used for the generation of AA metabolites in vitro as described in Methods. Extraction of metabolites, separation by thin layer chromatography and analysis of the radiochromatogram were performed as described in Methods. [3H]-5-HETE, [3H]-12-HETE and [3H]-15-HETE served as standards. The profiles were reproduced in 5 independent experiments.
330
on
Vol. 126,No.
1, 1985
BlOCHEMlCALANDBlOPHYSlCALRESEARCHCOMMUNlCATlONS
the
by TPA of such a metabolite
knowledge previously. lite not
induction
Lysed
in vitro, shown).
invading that
the epidermis
system.
by the
but
This
secondly,
in tumor
cell-free
system
promotion
(14),
Recently,
by directly
is
however,
an indirect
possible
that
by CsA in vivo.
immunosuppressive effects.
One possibility
leading CsA. CsA is
agent
to these It
remains based
also
various
Taken
CsA is is
that
effects
an open question on the
inhibition
to play
a very potent there
cell-free
respect
whether
the
of this 331
even at in vivo
Furthermore,
it
is
of PKC by TPA was results
inhibitor
this
of the
does not exclude,
indicate
process
unknown
the
TPA process
can be inhibited
immunosuppressive as yet
that
of several
is a common TPA-induced
and that
epidermal
the TPA effects
stimulation the
a central
a 50% inhibition
PKC. This
together,
pathway
of PKC by TPA
in this
CsA inhibited
the
metabolite
by CsA in the
caused
not
inhibitor.
in an epidermal
phloretin
(data
cyclooxygenase
of PKC by CsA in vivo.
following
howacid
the TPA-induced
on the stimulation
TPA-stimulated
inhibition
completely,
is thought
CsA was ineffective
the
a process
which
inhibitors
that
the
indomethacin
the
it
cell-
including
as a lipoxygenase
was not suppressed
not likely
inhibiting
than
act
C (PKC),
2x10e5M
PKC-activity. it
simply
by various
system
epidermal
nordihydroguaiaretic
that
rather
we reported
For instance,
Thus
suppressed
not
kinase
TPA-stimulated 5x10m4M.
CsA did
suppression
(15).
lipoxygenase
exclude
and that
in the
inhibitor
place
we cannot
such "TPA-activated"
quercetin,
first
leucocytes
with
was suppressed
cyclooxygenase
protein
system.
and on its
the
that
TPA-stimulated
metabolite
(data
metabolite
of AA in this
in the
metabo-
this
metabolism
not by the
along
to produce
inhibitors
indicates
was generated
Nevertheless,
AA metabolism
lipoxygenase
this
by "ordinary"
to inhibit
TPA-induced
not produce
generated
due to a contamination
The in vitro of the
was not
did
AA to HETEs efficiently
TPA treatment.
CsA was unable
and sesamol,
role
metabolized
leucocytes
in our assay
generation
and,
after
TPA caused
leucocytes.
shown).
they
Thus the metabolite
was found
ever,
from mouse blood
even though
in vivo
free
leucocytes
has not been reported
activity process.
by of
Vol. 126, No. 1, 1985
BIOCHEMICALAND
BIOPHYSICALRESEARCH
COMMUNICATIONS
ACKNOWLEDGEMENT We are
very
grateful
to Sandoz,
Basel,
for
the
gift
of cyclosporin
A.
REFERENCES 1
34 5 6
9 10 11 12 13 14 15
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