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L-Arginine stimulates an endogenous ADP-ribosyltransferase
Vol.
178,
August
No. 15,
BIOCHEMICAL
3, 1991
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages
1991
L-ARGININE
STIMULATES
Stefanie
Faculty
Received
AND
June
AN ENDOGENOUS ADP-RIBOSYLTBANSFERASE
Dimmeler
of Biology, University of 3,
848-855
and Bernhard
Department Konstanz,
BriineX
of Biological 7500 Konstanz,
Chemistry, F.R.G.
1991
Summary: An ubiquitous biochemical pathway known to synthesize nitric oxide (NO) from L-arginine has been identified in many cell types. Recent studies indicate that besides activating soluble guanylate cyclase NO is likely to have effects unrelated to the known signal transduction pathway. Activation of the soluble NO synthase stimulates an endogenous ADP-ribosylation of a predominant 39 kDa protein, known to be activated by NO releasing agents. This is demonstrated using the cytosolic fraction of rat cerebellum and HL-60 cells. The ADP-ribosylation is suppressed by the known NO synthase inhibitors N-nitro-L-arginine and N-methylL-arginine. These observations indicate that NO derived from its physiological precursor L-arginine activates an endogenous ADPribosyltransferase. B 1991 Academic Press, Inc.
The synthesis nitrogen to
least
inducible lived
of
atom
be at
of
two
is
producing
NO.
oxide
seems
pathway
that
macrophages
(7),
endothelium
(1,ll).
guanylate
to
an increase
in
has
been (8),
Initially
(12)
cyclase
of
vascular
messenger
should
appear
NO
the
an for
the
known
smooth
an
short-
ubiquitous example
cells as
is
of
be
to
and
in
(9,lO)
and
endotheliumto
activate
muscle,
cGMP and thereby
leading
regulating
be addressed.
used: tetrahydrobiopterin;
0006-291X/91 $1.50 Copyright 0 1991 by Academic Press, Inc. All rights of reproduction in any form reserved.
There
Formation
cerebellar
(EDRF)
second
(l-3).
guanidino
a constitutive
characterized
the
terminal
identified
factor
r To whom correspondence Abbreviations H4biopterin, dithiothreitol.
NO synthase,
neutrophils
the
the
accepted
(4-6)
biochemical
soluble
widely
of
nitric
relaxing
(NO) from
forms
radical
derived
oxide
L-arginine
isoenzyme free
nitric
SNP,
848
sodium
nitroprusside;
DTT,
Vol.
178, No. 3, 1991
the
vascular
tone
Besides
being
directly
activating
involved
system
in
soluble
guanylate
mimicked
cyclase.
by cGMP itself
hypothesis
that
the
or
NO also action
cerebellum
traced
to
of
the
lipophilic
cGMP derivatives, effects
in
in
the
NO and
NO-
activation
most biological
its
pathway
(20).
Therefore,
NO mediates
be
activated
found
action
back
by
seems to of
NO synthase
the
(14).
homeostasis
as a signalling
systems
is
function
wall
cyclase,
as in the
most
platelet
vessel
a role
with
as well
RESEARCH COMMUNICATIONS
cytostatic
play
vasodilators
generating
of
and
(18,19)
forebrain
as
guanylate
and to
Mechanistically
the
mediator
killing
(16,17)
vertebrate
as well
soluble
the
nervous
AND BIOPHYSICAL
(11,13-15)
a potent
in
macrophages the
BIOCHEMICAL
of
actions
are
supporting
by cGMP as the
second
messenger. Interestingly, that
several
NO has
cyclase. cell
It
additional has
been
proliferation
BALB/c
3T3
also
hepatocyte
protein
showed that
ribosylation
of
this
we proposed
ADP-ribosylation
Here synthase rat
reaction
we
like
stimulates
cerebellum
Therefore,
the
to the cytosol
in
ADP-ribosylation
agents
lack
849
cyclic soluble
NO inhibits
cause
tissues
still
way
the
ADP-
(24,25).
In
action
physiological
of
NO
significance
unknown.
of
a distinct
by
an
active
a 39 kDa protein
DMSO differentiated of
a
in
cGMP independent
NO generated
ADP-ribosylation and
cell
several
the is
that
in
cGMP independent
although
inhibit
calcium
that
a partially
a direct,
show
these
NO liberating
presently
free
indications
a 39 kDa protein
on an enzymatic of the
in
guanylate
compounds
achieved
is
concept
of
cytosolic
This
also
the
activation
because
are
synthesis
Own results
respect
decrease
fashion
There
support
NO containing
(21,22).
independent cyclase.
findings besides
shown that
and
guanylate
(23).
effects,
fibroblasts
nucleotide
recent
HL-60 protein
NO using
cells.
may occur
Vol.
178, No. 3, 1991
under
physiological
endogenous
BIOCHEMICAL
AND BIOPHYSICAL
conditions
by
released
from
various
sources.
Materials Preparation
NO
RESEARCH COMMUNICATIONS
of
a cytosolic
and Methods
fraction
from rat
cerebellum
was taken out and A female rat was killed using CO . The cerebellum 0,l mM EDTA, 10 mM washed twice in washing buffer i!0,32 M sucrose, HEPES, pH=7,4). All following procedures were carried out at 4 OC. The capillaries were carefully removed to avoid contaminations with erythrocytes. After washing the cerebellum once more in homogenizing buffer (10 mM HEPES, pH=7,4, 1 mM DTT) the tissue was homogenized and centrifuged (13.000 x g, 10 min). The supernatant was centrifuged at 160.000 x g for 30 min in an ultracentrifuge to Protein was determined using the obtain the cytosolic fraction. Bradford assay. Preparation
of
the
cytosolic
fraction
from
HL-60
cells
HL-60 celis were cultured in RPM1 1640 medium containing 1 mM 2 mM L-glutamine, 100 units/ml penicillin, 100 ).Jg/ml pyruvate, 1% non-essential amino acids and 10 % fetal calf streptomycin, serum at 5 % CO*. To induce differentiation along the neutrophil HL-60 cells (3 x 10 cells/ml) were cultured for 4 days pathway, in the presence of 1,25 % DMSO. The cells were pelleted at 200 x g for 5 min and washed twice with 10 mM HEPES, pH=7,4. Then the pellet was resuspended in buffer containing 10 mM HEPES, pH=7,4 with 5 I.LM pepstain A, 5 /.&M leupeptin, 100 I.~M PMSF and 10 PM sonicated. The cytosolic trypsin inhibitor and fraction was obtained as described for the peparation of the cerebellum cytoso1.
ADP-ribosylation was mainly carried out as previously described by BrUne et al (25). The cytosol (80 kg protein/assay) was incubated in 100 mM HEPES, pH=7,4, 2 mM DTT, 1 j.&M cold NAD and 0,5 PCi [32P]NAD/assay in a total volume of 80 ~1. After an incubation for 90 min (cerebellum cytosol) or 45 min (HL-60 cytosol) at 37 OC the acid insoluble proteins were precipitated with 20 % TCA and centrifuged for 10 min at 13.000 x g. The resulting pellets were washed twice with cold water saturated ether and were resolved in a 10 % sodium dodecyl sulfate-polyacrylamide gel (26). Gels were dried and exposed to KODAK X-ray films at -80 OC. The autoradiography was quantified densitometrically. Thiol solutions as well as solutions of N-nitro-L-arginine, sodium nitroprusside and NADPH were made fresh every day and were pH-balanced before use. Materials
[32P]NAD (800 jKi/mmol) was purchased from DuPont de Nemours, [14C]Methylated rainbow protein molecular weight markers 200 kDa) were bought from Amersham Corp. (6R)-5,6,7,8-TetrahydroL-biopterin was obtained from Dr. Schircks Laboratories Switzerland). All other chemicals were delivered by Sigma, Culture media and supplements were purchased from Laboratories (Grand Island, NY, USA) and fetal calf serum Biochrom KG (Berlin, FRG). 850
FRG. (14.3-
(Jona, F.R.G. Gibco from
Vol.
178, No. 3, 1991
BIOCHEMICAL
Results The
soluble
clearly
and
250
centrations
dependent
(27).
NO-synthase.
the
griess
Or5
neously
we
or
the
We succeeded
as the
ADP-ribosylation
cerebellum
concerning
the
synthase 39 kDa
incubation
like
(fig.l/lane
1 (lane
syltransferase
of
added
activity
NO-production
liberated like
for
ADP-ribosylation
the
the
activation
of
the
nitro-
activates
NO is
in
sponta-
SNP (sodium
if
an
the
en-
question
released
from of
the
cytosolic
NO syn-
NO synthase
as well
cytosolic
E) we detected
all
B).
fraction
of
did
not An
a low basal
39 kDa protein in
increase
in
(fig.l/lane activity
cofactors,
Parallel
the
cofactors
order
rat
active
ADP-ribosylation 851
using
to
cere-
stimulate
labelling
C).
We observed
compared
to
control
densitometrically.
or
5 mM N-methyl-L-arginine
NO of
NO synthase
revealed
that
SNP stimulated synthase the
the a 4-
specific
the
NO
of
by
experiments
suppress
activity
the
quantified
1 mM N-nitro-L-arginine
causing
with
from
occurs
was inhibited
activity. in
NO,
activating
ADP-ribose
inhibitors
of
address
of
a marked
with
A and
activation
cells.
in
without
in
con-
to
ADP-ribosyltransferase
increased
effective
by
finding
Addition
protein
pg/ml
in
order
also
ADP-ribosylation
results
higher
synthase
In
reaction
figure
cytosol.
the
agents
we looked
in
and HL-60
As shown in
results
be
cofactors
fraction
(3-morpholinosydnonimine)
39 kDa substrate
thase.
hibitors
that
NO containing
source
these
to
shown).
ADP-ribosylation
predominant
This
not
known
calmodulin,lO
cytosolic
measuring
demonstrated
SIN-l
physiological
fold
was assured
is
of PM;
(27)
ADP-ribosyltransferase.
whether
Addition
literature
(data
decomposing
dogenous
bellum
in
reaction
prusside)
cerebellum
the
to
14
This
Previously
rat
PM; NADPH, 200 PM; Ca*+,3
described
the
its
from
H4biopterin,
RESEARCH COMMUNICATIONS
Discussion
and
NO synthase
cofactor
(arginine,
AND BIOPHYSICAL
is
in-
the
NO
ADP-riboeven
39 kDa protein
more com-
Vol.
178,
No.
BIOCHEMICAL
3, 1991
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
A B C D E Fiuure 1. ADP-ribosylation using rat cerebellum cytosol. [32P]ADP-ribosylation was carried out as described in Materials and Methods section with following additions. Lane A: cofactors + 1 mM N-nitro-L-arginine; lane B: cofactors + 5 mM N-methyl-L-arginine; lane C: cofactors; lane D: 100 PM SNP; lane E: control; cofactors: 0.25 mM L-arginine, 0.2 mMNADPH, 0.5 PM H4biopterin, 3 FM Ca*+ and 10 pg/ml calmodulin. The shown autoradiograph is representative for three different preparations and reveals a molecular weight range of about 35 - 45 kD.
pared an
to
NO-liberating
about
2-fold
conditions two
agents increase
(fig.l;
further
dioactively
labelled,
stimulation Since
et
reached
al
(9)
linear
increase
ferase
activity
ADP-ribosylation
D to
E).
molecular
linearity an
using
30 to period
20 min,
ra-
from
the
with
the
human platelet
in
90 min. of
90 rat
slow
be explained.
90 min correlates
were
was increased
NO synthase
after
these
unchanged.
incubation the
only
cytosol
weights
between
30 min could
under
cerebellum
39 kDa protein
activity
observed
the
remained
showed that
up to
In
causes
a
The min. cere-
increase
The following
ADP-ribosyltranscytosol
stimulated
SNP (24). As
using In
the
after
a maximal
up to
the
they
showing
was maximal
of ADP-ribosylation
with
of
SNP (100 PM) which
higher
although
manner
Knowles
bellum
lane
slightly
The ADP-ribosylation time-dependent
of
compare
bands with
like
presented the
these
already
in
cytosolic cells
reported
the
figure fraction
existence by
Schmidt
2 the of of et
same
situation
was
DMSO differentiated an active al 852
(28).
HL-60
NO synthase Again
confirmed cells.
pathway
looking
for
was the
Vol.
178,
No.
3, 1991
BIOCHEMICAL
A
AND
B
BIOPHYSICAL
C
RESEARCH
D
COMMUNICATIONS
E
Figure 2. L-arginine stimulates an endogenous ADP-ribosylation. ADP-ribosylation was determined as described in Materials and Methods section using cytosol of DMSO differentiated HL-60 cells. Lane A: cofactors + N-methyl-L-arginine; lane B: cofactors + Nnitro-L-arginine; lane C: cofactors; lane D: 100 PM SNP; lane E: control. Other details as in Fig. 1.
39 kDa protein (fig.2/lane for
E).
the
clearly (fig.
we detected Addition
increased
ADP-ribosylation
C).
Again
B and A)
the
NO stimulated
the
NO synthase
et
one. al
also
of
Our results
revealed
the
of
cytosol
activity
associated
the
N-nitro-L-arginine have
with
rat
other
1,
caused
predominant
the
Besides
suppressed
to
fig.
required a
protein
and N-methyl-L-arginine for
D) of
differences
to
the
activity
cofactors
to
already
a higher cerebellum. bands
(fig.
NO synthase
inhibit
NO originating
NO liberated
%/lane
point
compared
Em-60
equivalent
inhibitors
inhibitors
Similar
(29).
known
(fig.
NO synthase
tive
and all
ADP-ribosylation.
ADP-ribosylation
ADP-ribosylation
N-nitro-L-arginine
pathway,
clearly
basal
L-arginine
NO synthase,
(fig.2jlane
results
of
cytosolic
a/lane
both
a low
from
SNP causes
39 kDa protein. the
from the
Although
ADP-ribosylation being
the
more effec-
been reported activity
our
in
by Gross HL-60
Furthermore,
the
1) was not
cells radio-
apparent
in
cells. These data
NO synthase shown before,
support
and not activates
our only the
view
that
NO derived
from
artificial
ADP-ribosylation 853
from
NO-donors of
the like
a cytosolic
cytosolic SNP,
as
39 kD
BIOCHEMICAL
Vol. 178, No. 3, 1991
Therefore,
the
endogenous
as an inter-
and
intracellular
protein. cells
AND BIOPHYSICAL
sufficient
signal
to
stimulate
generation
the
protein.
Although
the
sylation
is
unknown
we suggest
as the
only
guanylate
still cyclase
synthase
was
found
cells
with
the
cause
cGMP-independent
of
NO from
messenger
molecule
ADP-ribosylation
of
physiological
to
RESEARCH COMMUNICATIONS
significance that
NO not
intracellular
be associated of
rat
a
may be a a cytosolic
the
only
target.
in
ADP-ribosylation
of
different
ADP-ribohas
An active
cerebellum
cytosolic
soluble
and
protein
NO HL-60
and
NO effects. Acknowledsments
The
work
was supported
by the
Deutsche
Forschungsgemeinschaft
(SFB 156/A4) References 1.
Palmer, (Lond.),
R.M.J., Ashton, 333, 664-666
2.
R.M.J. and Moncada, Palmer, Comm. 158, 348-352
3.
Marletta,
4.
Miilsch, A., Schmiedeberg's
5.
Bredt, U.S.A.
M.
D.S.
87, D.J.
(1989)
TIBS
Bassenge, Arch.
D.S.
and Moncada, S.
14,
(1989)
S.
Biochem.
6.
Stuehr, 525
7.
Marietta, Wishnok,
8.
McCall, B.J.R.
9.
Knowles, R.G., Palacios, (1989) Proc. Natl. Acad.
S.H.
and Marletta,
(1990) M.A.
Proc.
(1987)
J.
T., Boughton-Smith, N.K., Palmer, and Moncada, S. (1988) Biochem. J.
10.
Bredt, U.S.A.
D.S. and Snyder, 86, 9030-9034
11.
Palmer, (Lond.)
R.M.J., Ferrige, 327, 524-526
Sci.
Palmer, U.S.A.
S.H.
(1989)
D.S.
Biophys.
Res.
Acad.
Immunol.
Sci.
139,
C.D.
518-
and
R.M.J., Whittle, 261, 293-296
R.M.J. and Moncada, 86, 5159-5162 Proc.
and Moncada,
854
Naunyn-
Natl.
M-A., Yoon, P.S., Iyengar, R., Leaf, J.S. (1988) Biochemistry 27, 8706-8711
M.,
Nature
488-492
E. and Busse, R. (1989) Pharmacol. 340, 767-770
and Snyder, 682-685
(1988)
Natl. S.
Acad. (1987)
Sci. Nature
S.
to
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R.F.
AND BIOPHYSICAL
and Zawadzki,
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12.
Furchgott, 373-376
13.
Hutchinson, P.J.A., J. Pharmacol. 141,
14.
Moncada, S., Hypertension
15.
Ignarro,
16.
Hibbs, J.B., 473-476
Taintor,
17.
Stuehr, 1555
and Nathan,
18.
Garthwaite, J. Nature (Lond.)
19.
Snyder,
20.
Bredt, U.S.A.
21.
G-g, 171,
22.
Garg , U.C.
23.
Curran, R.D., Stuehr, D.J., 5, 2085-2092
24.
Briine, 8458
B. and Lapetina,
E.G.
(1989)
J.
25.
Briine, B. and Lapetina, 279, 286-290
E.G.
(1990)
Arch.
26.
Laemmli,
27.
Mayer, B., 215-219.
28.
Schmidt, Letters
29.
Gross, S.S., and Griffith, 96-103
J.V.
Palmer, 445-451
R.M.J.
Palmer, R.M.J. 12, 365-372
L.J.
D.J.
(1989)
R.R.
Charles, S.J. 336, 385-388
U.C. and Hassid, 474-479 and Hassid,
R.K.
D.S. S.
John,
(Lond.) S.
31-36
(1989)
2. J.
(1987)
Expl.
(1991)
TIPS
(1990)
Proc.
12,
Science
Med.
and Chess-Williams,
169,
R.
Acad.
Sci.
Biophys.
A.
(1991)
J.
Chem. 266,
Kispert, P.H., Stadler, and Billiar, T.R. (1991)
(Lond.)
H.H.H.W., Seifert, 244, 357-360 Stuehr, D.J., O.W. (1990)
Biol.
227, (1990)
Res.
Comm.
9-12 J., FASEB J.
Chem. 264,
Biochem.
8455-
Biophys.
680-685 FEBS-Letters
R. and BShme, E. Aisaka, Biochem.
1543-
125-128
Natl.
Biol.
235,
(1988)
Biochem.
M. and Bbhme, E.
Eur.
(1988)
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Nature
288,
(1987)
A.
Ferrari, F.K., Simmons, R.L.
(1970)
E.A.
and VaVrin,
C.F.
D.S. and Snyder, 87, 682-685
3,
Nature
and Moncada,
and Higgs,
FASEB J.
S. and Bredt,
(1980)
(1989)
277, FEBS-
K., Jaffe, E.A., Levi, R. Biophys. Res. Comm. 170,
178,
August
No. 15,
BIOCHEMICAL
3, 1991
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages
1991
L-ARGININE
STIMULATES
Stefanie
Faculty
Received
AND
June
AN ENDOGENOUS ADP-RIBOSYLTBANSFERASE
Dimmeler
of Biology, University of 3,
848-855
and Bernhard
Department Konstanz,
BriineX
of Biological 7500 Konstanz,
Chemistry, F.R.G.
1991
Summary: An ubiquitous biochemical pathway known to synthesize nitric oxide (NO) from L-arginine has been identified in many cell types. Recent studies indicate that besides activating soluble guanylate cyclase NO is likely to have effects unrelated to the known signal transduction pathway. Activation of the soluble NO synthase stimulates an endogenous ADP-ribosylation of a predominant 39 kDa protein, known to be activated by NO releasing agents. This is demonstrated using the cytosolic fraction of rat cerebellum and HL-60 cells. The ADP-ribosylation is suppressed by the known NO synthase inhibitors N-nitro-L-arginine and N-methylL-arginine. These observations indicate that NO derived from its physiological precursor L-arginine activates an endogenous ADPribosyltransferase. B 1991 Academic Press, Inc.
The synthesis nitrogen to
least
inducible lived
of
atom
be at
of
two
is
producing
NO.
oxide
seems
pathway
that
macrophages
(7),
endothelium
(1,ll).
guanylate
to
an increase
in
has
been (8),
Initially
(12)
cyclase
of
vascular
messenger
should
appear
NO
the
an for
the
known
smooth
an
short-
ubiquitous example
cells as
is
of
be
to
and
in
(9,lO)
and
endotheliumto
activate
muscle,
cGMP and thereby
leading
regulating
be addressed.
used: tetrahydrobiopterin;
0006-291X/91 $1.50 Copyright 0 1991 by Academic Press, Inc. All rights of reproduction in any form reserved.
There
Formation
cerebellar
(EDRF)
second
(l-3).
guanidino
a constitutive
characterized
the
terminal
identified
factor
r To whom correspondence Abbreviations H4biopterin, dithiothreitol.
NO synthase,
neutrophils
the
the
accepted
(4-6)
biochemical
soluble
widely
of
nitric
relaxing
(NO) from
forms
radical
derived
oxide
L-arginine
isoenzyme free
nitric
SNP,
848
sodium
nitroprusside;
DTT,
Vol.
178, No. 3, 1991
the
vascular
tone
Besides
being
directly
activating
involved
system
in
soluble
guanylate
mimicked
cyclase.
by cGMP itself
hypothesis
that
the
or
NO also action
cerebellum
traced
to
of
the
lipophilic
cGMP derivatives, effects
in
in
the
NO and
NO-
activation
most biological
its
pathway
(20).
Therefore,
NO mediates
be
activated
found
action
back
by
seems to of
NO synthase
the
(14).
homeostasis
as a signalling
systems
is
function
wall
cyclase,
as in the
most
platelet
vessel
a role
with
as well
RESEARCH COMMUNICATIONS
cytostatic
play
vasodilators
generating
of
and
(18,19)
forebrain
as
guanylate
and to
Mechanistically
the
mediator
killing
(16,17)
vertebrate
as well
soluble
the
nervous
AND BIOPHYSICAL
(11,13-15)
a potent
in
macrophages the
BIOCHEMICAL
of
actions
are
supporting
by cGMP as the
second
messenger. Interestingly, that
several
NO has
cyclase. cell
It
additional has
been
proliferation
BALB/c
3T3
also
hepatocyte
protein
showed that
ribosylation
of
this
we proposed
ADP-ribosylation
Here synthase rat
reaction
we
like
stimulates
cerebellum
Therefore,
the
to the cytosol
in
ADP-ribosylation
agents
lack
849
cyclic soluble
NO inhibits
cause
tissues
still
way
the
ADP-
(24,25).
In
action
physiological
of
NO
significance
unknown.
of
a distinct
by
an
active
a 39 kDa protein
DMSO differentiated of
a
in
cGMP independent
NO generated
ADP-ribosylation and
cell
several
the is
that
in
cGMP independent
although
inhibit
calcium
that
a partially
a direct,
show
these
NO liberating
presently
free
indications
a 39 kDa protein
on an enzymatic of the
in
guanylate
compounds
achieved
is
concept
of
cytosolic
This
also
the
activation
because
are
synthesis
Own results
respect
decrease
fashion
There
support
NO containing
(21,22).
independent cyclase.
findings besides
shown that
and
guanylate
(23).
effects,
fibroblasts
nucleotide
recent
HL-60 protein
NO using
cells.
may occur
Vol.
178, No. 3, 1991
under
physiological
endogenous
BIOCHEMICAL
AND BIOPHYSICAL
conditions
by
released
from
various
sources.
Materials Preparation
NO
RESEARCH COMMUNICATIONS
of
a cytosolic
and Methods
fraction
from rat
cerebellum
was taken out and A female rat was killed using CO . The cerebellum 0,l mM EDTA, 10 mM washed twice in washing buffer i!0,32 M sucrose, HEPES, pH=7,4). All following procedures were carried out at 4 OC. The capillaries were carefully removed to avoid contaminations with erythrocytes. After washing the cerebellum once more in homogenizing buffer (10 mM HEPES, pH=7,4, 1 mM DTT) the tissue was homogenized and centrifuged (13.000 x g, 10 min). The supernatant was centrifuged at 160.000 x g for 30 min in an ultracentrifuge to Protein was determined using the obtain the cytosolic fraction. Bradford assay. Preparation
of
the
cytosolic
fraction
from
HL-60
cells
HL-60 celis were cultured in RPM1 1640 medium containing 1 mM 2 mM L-glutamine, 100 units/ml penicillin, 100 ).Jg/ml pyruvate, 1% non-essential amino acids and 10 % fetal calf streptomycin, serum at 5 % CO*. To induce differentiation along the neutrophil HL-60 cells (3 x 10 cells/ml) were cultured for 4 days pathway, in the presence of 1,25 % DMSO. The cells were pelleted at 200 x g for 5 min and washed twice with 10 mM HEPES, pH=7,4. Then the pellet was resuspended in buffer containing 10 mM HEPES, pH=7,4 with 5 I.LM pepstain A, 5 /.&M leupeptin, 100 I.~M PMSF and 10 PM sonicated. The cytosolic trypsin inhibitor and fraction was obtained as described for the peparation of the cerebellum cytoso1.
ADP-ribosylation was mainly carried out as previously described by BrUne et al (25). The cytosol (80 kg protein/assay) was incubated in 100 mM HEPES, pH=7,4, 2 mM DTT, 1 j.&M cold NAD and 0,5 PCi [32P]NAD/assay in a total volume of 80 ~1. After an incubation for 90 min (cerebellum cytosol) or 45 min (HL-60 cytosol) at 37 OC the acid insoluble proteins were precipitated with 20 % TCA and centrifuged for 10 min at 13.000 x g. The resulting pellets were washed twice with cold water saturated ether and were resolved in a 10 % sodium dodecyl sulfate-polyacrylamide gel (26). Gels were dried and exposed to KODAK X-ray films at -80 OC. The autoradiography was quantified densitometrically. Thiol solutions as well as solutions of N-nitro-L-arginine, sodium nitroprusside and NADPH were made fresh every day and were pH-balanced before use. Materials
[32P]NAD (800 jKi/mmol) was purchased from DuPont de Nemours, [14C]Methylated rainbow protein molecular weight markers 200 kDa) were bought from Amersham Corp. (6R)-5,6,7,8-TetrahydroL-biopterin was obtained from Dr. Schircks Laboratories Switzerland). All other chemicals were delivered by Sigma, Culture media and supplements were purchased from Laboratories (Grand Island, NY, USA) and fetal calf serum Biochrom KG (Berlin, FRG). 850
FRG. (14.3-
(Jona, F.R.G. Gibco from
Vol.
178, No. 3, 1991
BIOCHEMICAL
Results The
soluble
clearly
and
250
centrations
dependent
(27).
NO-synthase.
the
griess
Or5
neously
we
or
the
We succeeded
as the
ADP-ribosylation
cerebellum
concerning
the
synthase 39 kDa
incubation
like
(fig.l/lane
1 (lane
syltransferase
of
added
activity
NO-production
liberated like
for
ADP-ribosylation
the
the
activation
of
the
nitro-
activates
NO is
in
sponta-
SNP (sodium
if
an
the
en-
question
released
from of
the
cytosolic
NO syn-
NO synthase
as well
cytosolic
E) we detected
all
B).
fraction
of
did
not An
a low basal
39 kDa protein in
increase
in
(fig.l/lane activity
cofactors,
Parallel
the
cofactors
order
rat
active
ADP-ribosylation 851
using
to
cere-
stimulate
labelling
C).
We observed
compared
to
control
densitometrically.
or
5 mM N-methyl-L-arginine
NO of
NO synthase
revealed
that
SNP stimulated synthase the
the a 4-
specific
the
NO
of
by
experiments
suppress
activity
the
quantified
1 mM N-nitro-L-arginine
causing
with
from
occurs
was inhibited
activity. in
NO,
activating
ADP-ribose
inhibitors
of
address
of
a marked
with
A and
activation
cells.
in
without
in
con-
to
ADP-ribosyltransferase
increased
effective
by
finding
Addition
protein
pg/ml
in
order
also
ADP-ribosylation
results
higher
synthase
In
reaction
figure
cytosol.
the
agents
we looked
in
and HL-60
As shown in
results
be
cofactors
fraction
(3-morpholinosydnonimine)
39 kDa substrate
thase.
hibitors
that
NO containing
source
these
to
shown).
ADP-ribosylation
predominant
This
not
known
calmodulin,lO
cytosolic
measuring
demonstrated
SIN-l
physiological
fold
was assured
is
of PM;
(27)
ADP-ribosyltransferase.
whether
Addition
literature
(data
decomposing
dogenous
bellum
in
reaction
prusside)
cerebellum
the
to
14
This
Previously
rat
PM; NADPH, 200 PM; Ca*+,3
described
the
its
from
H4biopterin,
RESEARCH COMMUNICATIONS
Discussion
and
NO synthase
cofactor
(arginine,
AND BIOPHYSICAL
is
in-
the
NO
ADP-riboeven
39 kDa protein
more com-
Vol.
178,
No.
BIOCHEMICAL
3, 1991
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
A B C D E Fiuure 1. ADP-ribosylation using rat cerebellum cytosol. [32P]ADP-ribosylation was carried out as described in Materials and Methods section with following additions. Lane A: cofactors + 1 mM N-nitro-L-arginine; lane B: cofactors + 5 mM N-methyl-L-arginine; lane C: cofactors; lane D: 100 PM SNP; lane E: control; cofactors: 0.25 mM L-arginine, 0.2 mMNADPH, 0.5 PM H4biopterin, 3 FM Ca*+ and 10 pg/ml calmodulin. The shown autoradiograph is representative for three different preparations and reveals a molecular weight range of about 35 - 45 kD.
pared an
to
NO-liberating
about
2-fold
conditions two
agents increase
(fig.l;
further
dioactively
labelled,
stimulation Since
et
reached
al
(9)
linear
increase
ferase
activity
ADP-ribosylation
D to
E).
molecular
linearity an
using
30 to period
20 min,
ra-
from
the
with
the
human platelet
in
90 min. of
90 rat
slow
be explained.
90 min correlates
were
was increased
NO synthase
after
these
unchanged.
incubation the
only
cytosol
weights
between
30 min could
under
cerebellum
39 kDa protein
activity
observed
the
remained
showed that
up to
In
causes
a
The min. cere-
increase
The following
ADP-ribosyltranscytosol
stimulated
SNP (24). As
using In
the
after
a maximal
up to
the
they
showing
was maximal
of ADP-ribosylation
with
of
SNP (100 PM) which
higher
although
manner
Knowles
bellum
lane
slightly
The ADP-ribosylation time-dependent
of
compare
bands with
like
presented the
these
already
in
cytosolic cells
reported
the
figure fraction
existence by
Schmidt
2 the of of et
same
situation
was
DMSO differentiated an active al 852
(28).
HL-60
NO synthase Again
confirmed cells.
pathway
looking
for
was the
Vol.
178,
No.
3, 1991
BIOCHEMICAL
A
AND
B
BIOPHYSICAL
C
RESEARCH
D
COMMUNICATIONS
E
Figure 2. L-arginine stimulates an endogenous ADP-ribosylation. ADP-ribosylation was determined as described in Materials and Methods section using cytosol of DMSO differentiated HL-60 cells. Lane A: cofactors + N-methyl-L-arginine; lane B: cofactors + Nnitro-L-arginine; lane C: cofactors; lane D: 100 PM SNP; lane E: control. Other details as in Fig. 1.
39 kDa protein (fig.2/lane for
E).
the
clearly (fig.
we detected Addition
increased
ADP-ribosylation
C).
Again
B and A)
the
NO stimulated
the
NO synthase
et
one. al
also
of
Our results
revealed
the
of
cytosol
activity
associated
the
N-nitro-L-arginine have
with
rat
other
1,
caused
predominant
the
Besides
suppressed
to
fig.
required a
protein
and N-methyl-L-arginine for
D) of
differences
to
the
activity
cofactors
to
already
a higher cerebellum. bands
(fig.
NO synthase
inhibit
NO originating
NO liberated
%/lane
point
compared
Em-60
equivalent
inhibitors
inhibitors
Similar
(29).
known
(fig.
NO synthase
tive
and all
ADP-ribosylation.
ADP-ribosylation
ADP-ribosylation
N-nitro-L-arginine
pathway,
clearly
basal
L-arginine
NO synthase,
(fig.2jlane
results
of
cytosolic
a/lane
both
a low
from
SNP causes
39 kDa protein. the
from the
Although
ADP-ribosylation being
the
more effec-
been reported activity
our
in
by Gross HL-60
Furthermore,
the
1) was not
cells radio-
apparent
in
cells. These data
NO synthase shown before,
support
and not activates
our only the
view
that
NO derived
from
artificial
ADP-ribosylation 853
from
NO-donors of
the like
a cytosolic
cytosolic SNP,
as
39 kD
BIOCHEMICAL
Vol. 178, No. 3, 1991
Therefore,
the
endogenous
as an inter-
and
intracellular
protein. cells
AND BIOPHYSICAL
sufficient
signal
to
stimulate
generation
the
protein.
Although
the
sylation
is
unknown
we suggest
as the
only
guanylate
still cyclase
synthase
was
found
cells
with
the
cause
cGMP-independent
of
NO from
messenger
molecule
ADP-ribosylation
of
physiological
to
RESEARCH COMMUNICATIONS
significance that
NO not
intracellular
be associated of
rat
a
may be a a cytosolic
the
only
target.
in
ADP-ribosylation
of
different
ADP-ribohas
An active
cerebellum
cytosolic
soluble
and
protein
NO HL-60
and
NO effects. Acknowledsments
The
work
was supported
by the
Deutsche
Forschungsgemeinschaft
(SFB 156/A4) References 1.
Palmer, (Lond.),
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