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Immunocytochemical expression and localization of protein kinase C in bovine aortic endothelial cells
Vol. 189, No. 1, 1992 November 30, 1992
BIOCHEMICAL
IMMIJNOCYTOCHKMICAL EXPRESSION
AND BIOPHYSICAL
AND LOCALIZATION
AORTIC ENDOTHELIAL Oscar
R. Resales*,
Carlos
of *Medicine
E.
October
1,
C IN BOVINE
CELLS1
Sumpio+ Yale
and *Surgery, New Haven,
Received
OF PROTEIN KINASE
Isales*,MichaelNathanson*,
and Bauer Departments
RESEARCH COMMUNICATIONS Pages 40-46
University
School
of Medicine,
CT 06510
1992
Total PKC activity in BAEC incubated for 24 hrs in either 10% serum (FBS) or serum-deprived media (SDM) was similar. However, most of the activity (69%) in the FBS group was detected in the particulate fraction, while it was mainly in the cytosolic fraction (66%)in the SDM group. By confocal microscopy, there was diffuse cytoplasmic localization of the antibodies to the a and B PKC isoforms. y PKC was not detected. Treatment of FBS or SDM cells with a phorbol ester resulted in an increase in PKC activity with translocation to the particulate fraction. PKC a immunofluorescence redistributed to the perinuclear region whereas PKC B staining remained mostly cytosolic. Calphostin C, a PKC inhibitor, prevented the phorbol ester-induced increase in PKC activity and translocation. 0 1992 RcademlcPress, Inc.
Protein protein of
kinase
kinases
which
many cell
Cloning that
systems
studies encode
have
of
reported;
additional will
thought
to
calcium,
both
to
occur
a group
a variety
of
demonstrated of
in
to
of the following
a variety
of of
cell expression
the
activation cell
including of
the
a family exhibit
in
the
and drugs
(1).
of closely
related
genes
(2).
future.
cultured
of
40
of
y)
were (2)
PKC is
diacylglycerol
hydrolysis
and
of membrane
and particulate
fractions.
in membrane-associated has been However,
in BAEC have
1Supported by grants to B.E.S. from the NIH (HL40305, Administration. O.R.R. was an AHA Research Fellow,
and
been isolated
"translocation" BAEC (3).
B,
Activation
action
cytosolic This
tissue-specific (a,
subsequently
by signal-induced
in both
response
factors
genes
synergistic
PKC isoenzymes
0006-291X/92 $4.00 Copyright 0 1992 by Academic Press, Inc. All rights of reproduction in any form reserved.
transduction
distinct
different
of PKC is an increase
stimulation
types
signal
growth
a and 0 have
can be generated
PKC can be measured
An indication
which
(a,
and phospholipid-dependent
in the
three
be discovered
response
calcium-
PKC is
isoenzymes
cDNA clones
of which
of
hormones,
that
Initially,
probably
phospholipids.
patterns
to be involved
expression.
others
activity
is
appears
a number
patterns and
C (PKC)
not
HL47345), Connecticut
the been
PKC noted
in
individual described.
and the Veterans Affiliate.
Vol.
189,
No.
Using analysis
both
with
intracellular
BIOCHEMICAL
1, 1992
PKC activity
confocal
demonstrated
a predominant
isoform
of
13-acetate
(TPA),
Brief led
By immunofluorescent of
translocation
cytosolic
could
PKC.
be observed stimulation
to translocation staining
stimulation and increase
with
the
PKC activity against
the with of
effect
in
confluent R and of the
the BAEC
antibody with
immunocytochemistry of
calf
BAEC. y
serum By
isoforms
PKC,
a and R isoforms directed
on the
utilizing of
we
of PKC
against
to a particulate
a dense
perinuclear
PKC R remained was blocked
COMMUNICATIONS
the
y
12-O-tetradecanoylphorbol
of PKC activity
TPA whereas
and
a,
localization
PKC a displayed in activitv
RESEARCH
assays
we examined
directed
in BAEC. No staining
10 min
of
antibodies
BIOPHYSICAL
translocation
microscopy,
distribution
monoclonal
AND
in
bv caluhostin
fraction. pattern
the
cytosol.
after PKC
C.
METHODS Exoerimental Protocol BAEC were obtained by gentle scraping of the intima of calf thoracic aorta and maintained in DMEM F12 supplemented with 10% heat inactivated calf serum, 5 pg/ml deoxycytidine, 5 pg/ml thymidine, 1% penicillin-streptomycin and fungizone. BAEC were grown to confluence in 35 mm polystyrene wells and maintained in 10% calf serum for 24 hrs prior to experimentation (FBS) or serum-deprived for 24 hrs (SDM). BAEC were then treated with either the vehicle (0.1% DMSO) for 10 min or with 100 nM TPA dissolved in 0.1% DMSO for 10 min. In other studies, 0.05 pM calphostin C (Kamiya, Mountain View, CA) was activated by light (4) and added 30 min prior to the addition of TPA. Experiments were performed in quadruplicate. Cvtosol and Membrane Fractionation BAEC were washed twice with cold PBS and with buffer A (20 mM tris-HCl, pH 7.5, containing 2 mM EDTA, 0.5 mM EGTA, 2 mM PMSF, 25 pg/ml leupeptin, and 0.33 M sucrose) and scraped from the wells into 4 ml of buffer A. The suspension was homogenized and centrifuged at1500 g for 15 min. Completeness of cell disruption was confirmed by light microscopic evaluation of an aliquot of the suspension. The supernatant (cytosolic fraction) was saved and the pellet (membrane fraction) was washed in 5 ml of buffer B (20 mM tris-HCL, pH 7.5, containing 2 mM EDTA, 0.5 mM EGTA, 2 mM PMSF), centrifuged and resuspended in 4 ml of buffer B. Protein determinations were performed by the method of Bradford (5). To solubilize PKC associated with the membrane fraction, 1% NP-40 in buffer B was added and then centrifuged to obtain detergent-solubilized PKC from the membrane fraction. Both soluble and detergent-solubilized particulate fractions were applied to a DE-52 cellulose (Whatman) columnpolypropylene columns (Macalester Bicknell, New Haven, CT), equilibratedwithbuffer consisting of 20 mM Tris, 0.5 mM EDTA, 0.5 mM EGTA, and 5 mM R-mercaptoethanol (pH 7.5). After the columns were washed, PKC was eluted with equilibration buffer containing 150 mM NaCl. Protein Kinase C Assay Calciumand phospholipid dependent PKC activities were measured by determining 32P transferred from [Y-~~P]-ATP (specific activity lo-25 Ci/mmol, New England Nuclear, Boston, MA) to histone III-S as described by Kraft et al (6). In brief, l-3 pg of protein from the membrane or cytosolic fractions of BAEC were assayed in a reaction mixture (200 pl) containing 20 mM Tris-HCl (pH 7.5), 10 mM MgC12, 5 &ml 1,2-diolein, 200 pg/ml histone III-S, in the absence or presence of 0.5 mM CaC12 and 25 pg/ml phosphatidylserine. The reaction was initiated by addition of 10 pl of 0.4 mM [Y-~~P]ATP (250-500 cpm/pmol), for 10 min at 30°C. Twenty five pl aliquots were transferred to 1.5 cm2 Whatman P-81phosphocellulose the paper washed three times in 75 mM phosphoric acid, and 32P determined paper, by standard liquid scintillation techniques. PKC activity was determined by subtracting the amount of 32P incorporated into histone in the absence of calcium and phospholipid from the amount of 32P incorporated into histone in the presence of calcium and phospholipid and was expressed as nmoles of 32P incorporated/mg of protein/min. 41
Vol.
189, No. 1, 1992
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Immunocvtofluorescence of PKC Isoenzvmes Immunocytochemistry of PKC isoenzymes was examinedby slight modifications of previously reported methods (7,8). We used monoclonal antibodies directed against rabbit brain-PKC that react specifically with the a (MC-3a), B (MC-2a) and y (MC-la) subspecies of PKC (Seikagaku Kogyo Co., Ltd, Tokyo, Japan). The specificity of these antibodies for the different PKC-isoenzymes has been assessed by immunocytochemical analysis of the rabbit cerebellum (7). BAEC were fixed with 4% paraformaldehyde, permeabilized with 0.3% Triton X-100 for 30 min and incubated with 50 mM ammonium chloride for 15 min. After incubation with 1% bovine serum albumin in phosphate buffer solution (BSA/PBS) for 60 min, the preparation was incubated for 2 hrs at'room temperature with the PKC antibodies diluted in 1% BSA/PBS (1:20), washed three times with 1% BSA/PBS and subsequently exposed to the rhodamine-conjugated secondary antibody (l:lOO, 1% BSA/PBS) for 60 min. The preparation was then mounted with 50% glycerol and observed with a 40x or 63x objective on a Zeiss Axiovert microscope using a BioRad MRC-600 Confocal Imaging System. Aperture, gain and black level for imaging acquisition were maintained constant. No background or autofluorescence was visible at the chosen settings. Statistical Analvsis Results are expressed as mean+ standard deviation. The effect of different incubation media and TPA on PKC activity was analyzed by the unpaired Students' t test. Differences were considered significant at p < 0.05 level.
RESULTS PKC Activitv
in Cvtosolic
Total
PKC
nmoles/mg/min. fraction BAEC
to
100
of
calphostin
the
C prior
Total nmoles/mg/min, contrast activity of
arising
in
of
a reduction to
in
in cytosolic
a significant
(p
with
Localization Figure subspecies
of
cytosol. to
activity
PKC Isoenzvmes localized
that
from
the
in
the
30 min with drop
the
FBS
total
0.05
in total activity
the
fraction 1.6
BAEC
1.3f0.2
of
the
PKC
(69%),
with
only
31%
10 minutes
fraction
Pre-treatment PKC activity
In
majority
nmole/mg/min
the cytosolic
was
SDM BAEC (p
that
particulate
total
to
fraction.
100 nM TPA for
(3%). in
contributions
2 demonstrates were
the
60% of
unstimulated
to
drop
in a significant
of
1.520.2
fraction for
confluent
for
to
a commensurate
particulate
0.9kO.l
exposure
increased
with
1 demonstrates
decrease
equal
resulted (p-0.001)
PKC activity
PKC activity
After
particulate
in the particulate
the
total
fraction.
was
was
was in the membrane
to 9%. Pre-treatment
than
Figure
SDM BAEC activity
the
there
unstimulated
was higher
from
rise
translocation
Both
activity
in FBS BAEC was located
activity
of
while
fraction
BAEC
PKC activity
and 40% in the
SDM cells,
significant
led
contribution 91%,
nmoles/mg/min
which
to
total
to
total
cytosolic
to TPA stimulation,
fraction PKC
the
The
cytosolic
to 0.5fO.l
cytosolic
in
of
confluent
34% of the
10 min,
increased
PKC activity the
for
Fractions
unstimulated that
activity
(p-0.005).
activity
in
the
nM TPA
contribution pM
in
1 shows
66% of
nmoles/mg/min total
activity
Figure
and
and Particulate
(97%) with
0.05
to
0.650.1
also
caused
a
(p
with
associated
with
pM calphostin
C
nmoles/mg/min
and particulate
fractions.
in BAEC SDM BAEC expressed predominantly 42
in the
the
a and 13 isoforms
cytosol,
extending
of PKC. from
the
Vol.
189,
No.
1, 1992
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
2
Fizure
COMMUNICATIONS
*
1.
Effect of TPA on intracellular partitioning of protein kinase C. Confluent BAEC in either serum-derived media (SDM) or in media containing 10% FBS were exposed to either 0.1% DMSO (Basal) or 100 nM 12-O-tetradecanoylphorbol13-acetate (TPA) in 0.1% DMSO for 10 minutes. In some experiments 0.05 pM calphostin c (CC) was added for 30 min prior to stimulation with TPA. After homogenization and high speed centrifugation, PKC activities were measured in the cytosolic (clear bars) andmembrane (hatchedbars) fractions (nmoles/mgprotein/min, mean+ SD). *p
plasmamembrane observed. y or
to the nuclear
No staining
in
membrane
was observed
preparations
that
did
with
no significant
utilizing
not
the
include
intranuclear
antibody
primary
directed
staining against
antibodies
to
the
PKC
a or
R
isoforms. Incubation
of
redistribution stain
of
with
cytosol
and
although
r-24 TPA
remaining
PKC B. PKC a fluorescence
some intranuclear around
Pre-incubation
cytoplasmic of
the
plasma
0.05
serum,
membrane.
were
of both obtained
although
10
and less
significant intense
faint
The
fluorescent
revealed to
mild
43
of of
a marked
changes in
the
in
the
perinuclear
periphery
pattern
of of
perinuclear
TPA stimulation
experiments
translocation
caused
in the
a and B isoforms the
min
was most
C prior when
the
for
and very
cytosolic,
pM calphostin
staining
results calf
staining,
predominantly with
Similar presence
100
in PKC a immunofluorescence
pattern
region,
diffuse
SDM BAEC with
the
PKC B,
staining. resulted
in
PKC. were
performed
in the
PKC a immunofluorescence
Vol.
189, No. 1, 1992
BIOCHEMICAL
Basal
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
100 nM TPA
Calphostin
C
PKC a
PKC p
Figure
2,
Confocal fluorescence microscopy ofproteinkinase C 1ocalizationinBAEC. Images were focussed at the middle portion of the nucleus. (Left panel) BAEC were exposed to 0.1% DMSO for 10 min, fixed, and incubated with antibodies against PKC e, B, or y for 2 hrs, and subsequently exposed to the rhodamine-labelled anti-mouse IgG for 60 minutes (n-6). BAEC incubated without primary antibody or with PKC y failed to display immunofluorescence. (Middle panel) Exposure of BAEC to 100 nM TPA in 0.1% DMSO for 10 min, resulted in a shift of PKC a to the perinuclear region, whereas the fluorescent pattern of PKC B remained predominantly cytosolic (n-6). (Right panel) 0.05 PM calphostin C was added to BAEC for 30 min prior to exposure to 100 nM TPA in 0.1% DMSO for 10 min. There was diffuse cytoplasmic staining
of
both
was not
as striking
already
localized
a and
B isoforms
since
under
to
the
of
basal
PKC.
conditions
particulate
the majority
component
(Figure
of PKC activity
was
1).
DISCUSSION
Immunohistochemistrywithconfocal advantages
over
reconstruction accurate deprived
EC, to
antibody
which
PKC a and
The
Similarly,
under to
hence
we
of the
e and ( isozymes
of
PKC I3 cross-reacts cannot
current of
is
distinguish
primary with
(9).
In resting
of
expression
of
and a more
expressed
serumand
is
BAEC incubated
with
and
antibody
both
between
unavailability
PKC, the
fixing
similarly in
resolution
upon
distribution
was observed
a variety
distinct
includinghigher
distortion
I3 immunofluorescence No staining
antibody
and
microscopy
may suffer
or fluorescence
cytosol.
in view
8,
of stain
PKC y even
subspecies, the
fluorescence
the
to
dilutions.
still
conventional of structures
assessment
localized
fluorescencemicroscopyoffers
secondary the
131 and
these
antibodies these
two
82 PKC
isoenzymes.
directed
subspecies
our
against in BAEC is
unknown. The ratio
according
to cell
of the type,
membrane
to soluble
degree
of confluence 44
PKC activity
in resting
and differentiation
cells
varies
and incubation
Vol.
189,
No.
media.
In
about in
this
study,
This
observation
0.5.
the
BIOCHEMICAL
1, 1992
same cells,
cytosol. (10)
cytosol
or
ratio.
activity
For
maintained
of change
to membrane
cytosol
Recent
reports
results
not
fraction with
only
other in
cell
binding
to
of
PKC isoenzymes
activation
of
this
in
a higher
that
the
and NIH-3T3
In contrast,
cells
membrane
67% of the cells
percentage
Nonetheless,
our
to
total
PKC
incubated
in
in confluent
BAEC
TPA for
effects
10 minutes
perinuclear
staining
stained
the for
different
cell
perhaps
reflecting include
both
(16)
reported
that
dibutyrate,
membrane. NIH
Leach
studies,
systems of
HL60
(17)
using
et
types
another. with
in BAEC.
100 nM
mostly
PKC ct to
the
cytosolic
and
examined
al
(10)
also 45
studies
have
as intact
cells.
with
bryostatin
1,
the
of a PKC-like
increase showed
been diverse,
against pattern,
Hocevar
13-acetate in nuclear increased
et
al
phorbol
activity
to the
localization
PKC a. while
used
and not
immunocytochemical
directed
several
protocols
as well
cytoplasmic
a specific
soughtin
and experimental
withphorbol12-myristate
of PKC with Halsey
cells
antibodies
a diffuse
of cells
prevent
treatment of
been
of these
and translocation
et al in
relocation
PKC localizationhas of cell
the activation
3T3 cells
Treatment
range
treatment
PKC 01 localized
in a redistribution
wide
for
not
that
PKC R remained
The results
reconstituted
caused
PKC in
nuclear
and tissues. the
while
but
expression
intense
the
or may mask the
site
suggest
One of to assay
region.
or against
types
which
regions
perinuclear
one
studies
and
the
completely
compartments
of PKC isotype
an apparent
throughout (1).
may not
in
(6,17). how
effects
at
also
may explain
fractionation
cellular
BAEC. of PKC
but
elements
Fixation
fed
structures
of proteins
antibody
on patterns
caused
(12,13),
biological
putative
serum activation
and nuclear
of subcellular
monoclonal
that
lipids
in a
was detected
and the
cellular
and diverse
and intranuclear
Evidence
membrane
than
of PKC activity
PKC activity
demonstrated
(14,15)
EC, phorbol
rather
Translocation
in phosphorylation
other
one
including
PKC activity
deprived
different
immunofluorescent
TPA has different
have
bywesternblot.
from by
types,
>91% of
serum
is the absence
or PKC isozymes recognized
that
the
to
of multiple
loss of PKC isozymes eptiope
cell
(3,12).
plasma
results
of our study
PKC activity
these
evidence
expressed
endothelial
of
elements
enzyme
and regulation
limitations
to
reported
inmany
systems
Translocation
unstained.
BAEC was
BALB/c-3T3
display
a similar
such
in both
cytoskeletal
cells,
(3)
mainly in
EC (11).
arterial
PKC activity
occurred,
to
of
is
media
al
deprived
immunocytochemical
reported
a redistribution
translocation
nuclear
et
studies
in total
particulate
faintly
our
aortic
We found
EC causes
from
cell
been
pulmonary
from previous
treatment
the
with
porcine
Myers
associated.
quantitative in
confluent-serum
in serum-rich
bovine
COMMUNICATIONS
in 10% FBS.
As expected ester
have
quiescent
instance,
10% FBS was membrane
in
RESEARCH
PKC immunofluorescence
incubated
in confluent
ratio
ratios
sparse,
growing
BIOPHYSICAL
is in agreement
activity
and in
actively
activity
in which
Similar
cells
the
AND
the
In
control
nuclei
were
(PMA) resulted PKC. In contrast
perinuclear
staining
Vol.
in
189,
No.
PMA-treated
activity
BIOCHEMICAL
1, 1992
3T3-Ll
cells
was associated
using
only
with
AND
BIOPHYSICAL
a polyclonal nonnuclear
RESEARCH
antibody
COMMUNICATIONS
to
membranes
PKG. However,
and not
with
the
PKC
nuclear
fraction. affect and
The
exact
role
the
transcription
interferon
proteins
PKC in
been
and only
systems,
envelope.
nucleus
PMA-stimulated reported,
II
some of Thus,
these
the
is
not
including
yet
lamin
(19). proteins,
B (16),
such
Phorbol
plasminogen of
Most of these
physiological
known.
c-fos,
phosphorylation
including
and DNA topoisomerase
nuclear
the
of many genes,
(17).
has
proteins
of
studies
as lamin
PKC nuclear
activator
a variety histones used B,
are
esters
of
nuclear
(18),
matrix
reconstitution located
substrates
in
have
not
the been
identified. In that
BAEC express
treatment
of
membrane areas.
the
present
PKC a and
EC results
fractions, Further
isoenzymes insights
in
summary,
in to the
in
the
multiple
we provide
I3 isotypes,
but
immunocytochemical not
y.
translocation
of
PKC activity
a and 13 isoforms
of
PKC appear
understanding response
study
of
to
different
regulatory
the
intracellular agonists effects
phorbol
from to
location and
of
Although
antagonists
evidence
the
ester
cytosol
shift
to
different
of
the
different
to
may contribute
PKC.
REFERENCES
1. Nishizuka, Y.. (1988) Nature 334: 661-665. 2. Blackshear P.J. (1988) Am. J. Med. Sci. 296: 231-240. 3. Myers, C.L., J.S. Laze, B.R. Pitt. (1989) Am. J. Physiol. 257: L253-L258. 4. Bruns R.F., Miller F.D., Merriman R.L., Howbert J.J., Heath W.F., Kobayashi E ., Takahashi I., Tamaoki T., Nakano H. (1991) Biochem Biophy Res Comm 176:288293. 5. Bradford, M.M. (1976) Anal. Biochem. 72:248-254. 6. Kraft, A.S., W.B. Anderson, H.L. Cooper, J.J. Sando. (1982) J. Biol. Chem. 257: 13193-13196. 7. Hidaka, H., T. Tanaka, K. Onoda, H. Ohta, M. Watanabe, Y. Itoh, M. Tsurudone, K. Izutsu, T. Yoshida. (1988) J. Biol. Chem. 263: 4523-4526. 8. Leach, K.L., E. A. Powers, J.C. McGuire, L. Dong, S. Jaken. (1988) J. Biol. Chem. 263: 13223-13230. 9. Wilson, T. (1990) Confocalmicroscopy. pp 325-335. Academic Press, San Diego, 10. Halsey, D.L., P.R. Girard, J. F. Kuo, P.J. Blackshear. (1987) J. Biol. Chem. 262: 2234-2243. 11. Uratsuji, Y., P.E. DiCorleto. (1988) J. Cell Physiol. 136: 431-438. 12. Shoji, M., P.R. Girard, G.J. Mazzei, W.R. Vogler, J.F. Kuo. (1986) Biochem. Biophys. Res. Commun. 135: 1144-1149. 13. Ito, T., T. Tanaka, T. Yoshida, K. Onoda, H. Ghta, M. Hagiwara, Y. Itoh, M. Ogura, H. Saito, H. Hidaka. (1988) J. Cell Biol. 107: 929-937. 14. Jaken, S., K. Leach, T. Klauck. (1989) J. Cell Biol. 109: 697-704. L. Cheever, H. Khaner, P.C. Simpson. (1990) 15. Mochly-Rosen D., C.J. Henrich, Cell Regulation 1: 693-706. 16. Hocevar, B.A., A.P. Fields. (1991) J. Biol. Chem. 266: 28-33. V.A. Ruff, S. Jaken, S. Kaufmann. (1989) J. Cell 17. Leach, K.L., E.A. Powers, Biol. 109: 685-695. 18. Butler, A.P., G.V. Byus, T.J. Slaga.(1986) J. Biol. Chem. 261: 9421-9425. 19. SaLyoun, N., M. Wolf, J. Besterman, T.S. Hsieh, P. Cuatrecasas. (1986) Proc. Natl. Acad. Sci. USA. 83: 1603-1607.
46
BIOCHEMICAL
IMMIJNOCYTOCHKMICAL EXPRESSION
AND BIOPHYSICAL
AND LOCALIZATION
AORTIC ENDOTHELIAL Oscar
R. Resales*,
Carlos
of *Medicine
E.
October
1,
C IN BOVINE
CELLS1
Sumpio+ Yale
and *Surgery, New Haven,
Received
OF PROTEIN KINASE
Isales*,MichaelNathanson*,
and Bauer Departments
RESEARCH COMMUNICATIONS Pages 40-46
University
School
of Medicine,
CT 06510
1992
Total PKC activity in BAEC incubated for 24 hrs in either 10% serum (FBS) or serum-deprived media (SDM) was similar. However, most of the activity (69%) in the FBS group was detected in the particulate fraction, while it was mainly in the cytosolic fraction (66%)in the SDM group. By confocal microscopy, there was diffuse cytoplasmic localization of the antibodies to the a and B PKC isoforms. y PKC was not detected. Treatment of FBS or SDM cells with a phorbol ester resulted in an increase in PKC activity with translocation to the particulate fraction. PKC a immunofluorescence redistributed to the perinuclear region whereas PKC B staining remained mostly cytosolic. Calphostin C, a PKC inhibitor, prevented the phorbol ester-induced increase in PKC activity and translocation. 0 1992 RcademlcPress, Inc.
Protein protein of
kinase
kinases
which
many cell
Cloning that
systems
studies encode
have
of
reported;
additional will
thought
to
calcium,
both
to
occur
a group
a variety
of
demonstrated of
in
to
of the following
a variety
of of
cell expression
the
activation cell
including of
the
a family exhibit
in
the
and drugs
(1).
of closely
related
genes
(2).
future.
cultured
of
40
of
y)
were (2)
PKC is
diacylglycerol
hydrolysis
and
of membrane
and particulate
fractions.
in membrane-associated has been However,
in BAEC have
1Supported by grants to B.E.S. from the NIH (HL40305, Administration. O.R.R. was an AHA Research Fellow,
and
been isolated
"translocation" BAEC (3).
B,
Activation
action
cytosolic This
tissue-specific (a,
subsequently
by signal-induced
in both
response
factors
genes
synergistic
PKC isoenzymes
0006-291X/92 $4.00 Copyright 0 1992 by Academic Press, Inc. All rights of reproduction in any form reserved.
transduction
distinct
different
of PKC is an increase
stimulation
types
signal
growth
a and 0 have
can be generated
PKC can be measured
An indication
which
(a,
and phospholipid-dependent
in the
three
be discovered
response
calcium-
PKC is
isoenzymes
cDNA clones
of which
of
hormones,
that
Initially,
probably
phospholipids.
patterns
to be involved
expression.
others
activity
is
appears
a number
patterns and
C (PKC)
not
HL47345), Connecticut
the been
PKC noted
in
individual described.
and the Veterans Affiliate.
Vol.
189,
No.
Using analysis
both
with
intracellular
BIOCHEMICAL
1, 1992
PKC activity
confocal
demonstrated
a predominant
isoform
of
13-acetate
(TPA),
Brief led
By immunofluorescent of
translocation
cytosolic
could
PKC.
be observed stimulation
to translocation staining
stimulation and increase
with
the
PKC activity against
the with of
effect
in
confluent R and of the
the BAEC
antibody with
immunocytochemistry of
calf
BAEC. y
serum By
isoforms
PKC,
a and R isoforms directed
on the
utilizing of
we
of PKC
against
to a particulate
a dense
perinuclear
PKC R remained was blocked
COMMUNICATIONS
the
y
12-O-tetradecanoylphorbol
of PKC activity
TPA whereas
and
a,
localization
PKC a displayed in activitv
RESEARCH
assays
we examined
directed
in BAEC. No staining
10 min
of
antibodies
BIOPHYSICAL
translocation
microscopy,
distribution
monoclonal
AND
in
bv caluhostin
fraction. pattern
the
cytosol.
after PKC
C.
METHODS Exoerimental Protocol BAEC were obtained by gentle scraping of the intima of calf thoracic aorta and maintained in DMEM F12 supplemented with 10% heat inactivated calf serum, 5 pg/ml deoxycytidine, 5 pg/ml thymidine, 1% penicillin-streptomycin and fungizone. BAEC were grown to confluence in 35 mm polystyrene wells and maintained in 10% calf serum for 24 hrs prior to experimentation (FBS) or serum-deprived for 24 hrs (SDM). BAEC were then treated with either the vehicle (0.1% DMSO) for 10 min or with 100 nM TPA dissolved in 0.1% DMSO for 10 min. In other studies, 0.05 pM calphostin C (Kamiya, Mountain View, CA) was activated by light (4) and added 30 min prior to the addition of TPA. Experiments were performed in quadruplicate. Cvtosol and Membrane Fractionation BAEC were washed twice with cold PBS and with buffer A (20 mM tris-HCl, pH 7.5, containing 2 mM EDTA, 0.5 mM EGTA, 2 mM PMSF, 25 pg/ml leupeptin, and 0.33 M sucrose) and scraped from the wells into 4 ml of buffer A. The suspension was homogenized and centrifuged at1500 g for 15 min. Completeness of cell disruption was confirmed by light microscopic evaluation of an aliquot of the suspension. The supernatant (cytosolic fraction) was saved and the pellet (membrane fraction) was washed in 5 ml of buffer B (20 mM tris-HCL, pH 7.5, containing 2 mM EDTA, 0.5 mM EGTA, 2 mM PMSF), centrifuged and resuspended in 4 ml of buffer B. Protein determinations were performed by the method of Bradford (5). To solubilize PKC associated with the membrane fraction, 1% NP-40 in buffer B was added and then centrifuged to obtain detergent-solubilized PKC from the membrane fraction. Both soluble and detergent-solubilized particulate fractions were applied to a DE-52 cellulose (Whatman) columnpolypropylene columns (Macalester Bicknell, New Haven, CT), equilibratedwithbuffer consisting of 20 mM Tris, 0.5 mM EDTA, 0.5 mM EGTA, and 5 mM R-mercaptoethanol (pH 7.5). After the columns were washed, PKC was eluted with equilibration buffer containing 150 mM NaCl. Protein Kinase C Assay Calciumand phospholipid dependent PKC activities were measured by determining 32P transferred from [Y-~~P]-ATP (specific activity lo-25 Ci/mmol, New England Nuclear, Boston, MA) to histone III-S as described by Kraft et al (6). In brief, l-3 pg of protein from the membrane or cytosolic fractions of BAEC were assayed in a reaction mixture (200 pl) containing 20 mM Tris-HCl (pH 7.5), 10 mM MgC12, 5 &ml 1,2-diolein, 200 pg/ml histone III-S, in the absence or presence of 0.5 mM CaC12 and 25 pg/ml phosphatidylserine. The reaction was initiated by addition of 10 pl of 0.4 mM [Y-~~P]ATP (250-500 cpm/pmol), for 10 min at 30°C. Twenty five pl aliquots were transferred to 1.5 cm2 Whatman P-81phosphocellulose the paper washed three times in 75 mM phosphoric acid, and 32P determined paper, by standard liquid scintillation techniques. PKC activity was determined by subtracting the amount of 32P incorporated into histone in the absence of calcium and phospholipid from the amount of 32P incorporated into histone in the presence of calcium and phospholipid and was expressed as nmoles of 32P incorporated/mg of protein/min. 41
Vol.
189, No. 1, 1992
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Immunocvtofluorescence of PKC Isoenzvmes Immunocytochemistry of PKC isoenzymes was examinedby slight modifications of previously reported methods (7,8). We used monoclonal antibodies directed against rabbit brain-PKC that react specifically with the a (MC-3a), B (MC-2a) and y (MC-la) subspecies of PKC (Seikagaku Kogyo Co., Ltd, Tokyo, Japan). The specificity of these antibodies for the different PKC-isoenzymes has been assessed by immunocytochemical analysis of the rabbit cerebellum (7). BAEC were fixed with 4% paraformaldehyde, permeabilized with 0.3% Triton X-100 for 30 min and incubated with 50 mM ammonium chloride for 15 min. After incubation with 1% bovine serum albumin in phosphate buffer solution (BSA/PBS) for 60 min, the preparation was incubated for 2 hrs at'room temperature with the PKC antibodies diluted in 1% BSA/PBS (1:20), washed three times with 1% BSA/PBS and subsequently exposed to the rhodamine-conjugated secondary antibody (l:lOO, 1% BSA/PBS) for 60 min. The preparation was then mounted with 50% glycerol and observed with a 40x or 63x objective on a Zeiss Axiovert microscope using a BioRad MRC-600 Confocal Imaging System. Aperture, gain and black level for imaging acquisition were maintained constant. No background or autofluorescence was visible at the chosen settings. Statistical Analvsis Results are expressed as mean+ standard deviation. The effect of different incubation media and TPA on PKC activity was analyzed by the unpaired Students' t test. Differences were considered significant at p < 0.05 level.
RESULTS PKC Activitv
in Cvtosolic
Total
PKC
nmoles/mg/min. fraction BAEC
to
100
of
calphostin
the
C prior
Total nmoles/mg/min, contrast activity of
arising
in
of
a reduction to
in
in cytosolic
a significant
(p
with
Localization Figure subspecies
of
cytosol. to
activity
PKC Isoenzvmes localized
that
from
the
in
the
30 min with drop
the
FBS
total
0.05
in total activity
the
fraction 1.6
BAEC
1.3f0.2
of
the
PKC
(69%),
with
only
31%
10 minutes
fraction
Pre-treatment PKC activity
In
majority
nmole/mg/min
the cytosolic
was
SDM BAEC (p
that
particulate
total
to
fraction.
100 nM TPA for
(3%). in
contributions
2 demonstrates were
the
60% of
unstimulated
to
drop
in a significant
of
1.520.2
fraction for
confluent
for
to
a commensurate
particulate
0.9kO.l
exposure
increased
with
1 demonstrates
decrease
equal
resulted (p-0.001)
PKC activity
PKC activity
After
particulate
in the particulate
the
total
fraction.
was
was
was in the membrane
to 9%. Pre-treatment
than
Figure
SDM BAEC activity
the
there
unstimulated
was higher
from
rise
translocation
Both
activity
in FBS BAEC was located
activity
of
while
fraction
BAEC
PKC activity
and 40% in the
SDM cells,
significant
led
contribution 91%,
nmoles/mg/min
which
to
total
to
total
cytosolic
to TPA stimulation,
fraction PKC
the
The
cytosolic
to 0.5fO.l
cytosolic
in
of
confluent
34% of the
10 min,
increased
PKC activity the
for
Fractions
unstimulated that
activity
(p-0.005).
activity
in
the
nM TPA
contribution pM
in
1 shows
66% of
nmoles/mg/min total
activity
Figure
and
and Particulate
(97%) with
0.05
to
0.650.1
also
caused
a
(p
with
associated
with
pM calphostin
C
nmoles/mg/min
and particulate
fractions.
in BAEC SDM BAEC expressed predominantly 42
in the
the
a and 13 isoforms
cytosol,
extending
of PKC. from
the
Vol.
189,
No.
1, 1992
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
2
Fizure
COMMUNICATIONS
*
1.
Effect of TPA on intracellular partitioning of protein kinase C. Confluent BAEC in either serum-derived media (SDM) or in media containing 10% FBS were exposed to either 0.1% DMSO (Basal) or 100 nM 12-O-tetradecanoylphorbol13-acetate (TPA) in 0.1% DMSO for 10 minutes. In some experiments 0.05 pM calphostin c (CC) was added for 30 min prior to stimulation with TPA. After homogenization and high speed centrifugation, PKC activities were measured in the cytosolic (clear bars) andmembrane (hatchedbars) fractions (nmoles/mgprotein/min, mean+ SD). *p
plasmamembrane observed. y or
to the nuclear
No staining
in
membrane
was observed
preparations
that
did
with
no significant
utilizing
not
the
include
intranuclear
antibody
primary
directed
staining against
antibodies
to
the
PKC
a or
R
isoforms. Incubation
of
redistribution stain
of
with
cytosol
and
although
r-24 TPA
remaining
PKC B. PKC a fluorescence
some intranuclear around
Pre-incubation
cytoplasmic of
the
plasma
0.05
serum,
membrane.
were
of both obtained
although
10
and less
significant intense
faint
The
fluorescent
revealed to
mild
43
of of
a marked
changes in
the
in
the
perinuclear
periphery
pattern
of of
perinuclear
TPA stimulation
experiments
translocation
caused
in the
a and B isoforms the
min
was most
C prior when
the
for
and very
cytosolic,
pM calphostin
staining
results calf
staining,
predominantly with
Similar presence
100
in PKC a immunofluorescence
pattern
region,
diffuse
SDM BAEC with
the
PKC B,
staining. resulted
in
PKC. were
performed
in the
PKC a immunofluorescence
Vol.
189, No. 1, 1992
BIOCHEMICAL
Basal
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
100 nM TPA
Calphostin
C
PKC a
PKC p
Figure
2,
Confocal fluorescence microscopy ofproteinkinase C 1ocalizationinBAEC. Images were focussed at the middle portion of the nucleus. (Left panel) BAEC were exposed to 0.1% DMSO for 10 min, fixed, and incubated with antibodies against PKC e, B, or y for 2 hrs, and subsequently exposed to the rhodamine-labelled anti-mouse IgG for 60 minutes (n-6). BAEC incubated without primary antibody or with PKC y failed to display immunofluorescence. (Middle panel) Exposure of BAEC to 100 nM TPA in 0.1% DMSO for 10 min, resulted in a shift of PKC a to the perinuclear region, whereas the fluorescent pattern of PKC B remained predominantly cytosolic (n-6). (Right panel) 0.05 PM calphostin C was added to BAEC for 30 min prior to exposure to 100 nM TPA in 0.1% DMSO for 10 min. There was diffuse cytoplasmic staining
of
both
was not
as striking
already
localized
a and
B isoforms
since
under
to
the
of
basal
PKC.
conditions
particulate
the majority
component
(Figure
of PKC activity
was
1).
DISCUSSION
Immunohistochemistrywithconfocal advantages
over
reconstruction accurate deprived
EC, to
antibody
which
PKC a and
The
Similarly,
under to
hence
we
of the
e and ( isozymes
of
PKC I3 cross-reacts cannot
current of
is
distinguish
primary with
(9).
In resting
of
expression
of
and a more
expressed
serumand
is
BAEC incubated
with
and
antibody
both
between
unavailability
PKC, the
fixing
similarly in
resolution
upon
distribution
was observed
a variety
distinct
includinghigher
distortion
I3 immunofluorescence No staining
antibody
and
microscopy
may suffer
or fluorescence
cytosol.
in view
8,
of stain
PKC y even
subspecies, the
fluorescence
the
to
dilutions.
still
conventional of structures
assessment
localized
fluorescencemicroscopyoffers
secondary the
131 and
these
antibodies these
two
82 PKC
isoenzymes.
directed
subspecies
our
against in BAEC is
unknown. The ratio
according
to cell
of the type,
membrane
to soluble
degree
of confluence 44
PKC activity
in resting
and differentiation
cells
varies
and incubation
Vol.
189,
No.
media.
In
about in
this
study,
This
observation
0.5.
the
BIOCHEMICAL
1, 1992
same cells,
cytosol. (10)
cytosol
or
ratio.
activity
For
maintained
of change
to membrane
cytosol
Recent
reports
results
not
fraction with
only
other in
cell
binding
to
of
PKC isoenzymes
activation
of
this
in
a higher
that
the
and NIH-3T3
In contrast,
cells
membrane
67% of the cells
percentage
Nonetheless,
our
to
total
PKC
incubated
in
in confluent
BAEC
TPA for
effects
10 minutes
perinuclear
staining
stained
the for
different
cell
perhaps
reflecting include
both
(16)
reported
that
dibutyrate,
membrane. NIH
Leach
studies,
systems of
HL60
(17)
using
et
types
another. with
in BAEC.
100 nM
mostly
PKC ct to
the
cytosolic
and
examined
al
(10)
also 45
studies
have
as intact
cells.
with
bryostatin
1,
the
of a PKC-like
increase showed
been diverse,
against pattern,
Hocevar
13-acetate in nuclear increased
et
al
phorbol
activity
to the
localization
PKC a. while
used
and not
immunocytochemical
directed
several
protocols
as well
cytoplasmic
a specific
soughtin
and experimental
withphorbol12-myristate
of PKC with Halsey
cells
antibodies
a diffuse
of cells
prevent
treatment of
been
of these
and translocation
et al in
relocation
PKC localizationhas of cell
the activation
3T3 cells
Treatment
range
treatment
PKC 01 localized
in a redistribution
wide
for
not
that
PKC R remained
The results
reconstituted
caused
PKC in
nuclear
and tissues. the
while
but
expression
intense
the
or may mask the
site
suggest
One of to assay
region.
or against
types
which
regions
perinuclear
one
studies
and
the
completely
compartments
of PKC isotype
an apparent
throughout (1).
may not
in
(6,17). how
effects
at
also
may explain
fractionation
cellular
BAEC. of PKC
but
elements
Fixation
fed
structures
of proteins
antibody
on patterns
caused
(12,13),
biological
putative
serum activation
and nuclear
of subcellular
monoclonal
that
lipids
in a
was detected
and the
cellular
and diverse
and intranuclear
Evidence
membrane
than
of PKC activity
PKC activity
demonstrated
(14,15)
EC, phorbol
rather
Translocation
in phosphorylation
other
one
including
PKC activity
deprived
different
immunofluorescent
TPA has different
have
bywesternblot.
from by
types,
>91% of
serum
is the absence
or PKC isozymes recognized
that
the
to
of multiple
loss of PKC isozymes eptiope
cell
(3,12).
plasma
results
of our study
PKC activity
these
evidence
expressed
endothelial
of
elements
enzyme
and regulation
limitations
to
reported
inmany
systems
Translocation
unstained.
BAEC was
BALB/c-3T3
display
a similar
such
in both
cytoskeletal
cells,
(3)
mainly in
EC (11).
arterial
PKC activity
occurred,
to
of
is
media
al
deprived
immunocytochemical
reported
a redistribution
translocation
nuclear
et
studies
in total
particulate
faintly
our
aortic
We found
EC causes
from
cell
been
pulmonary
from previous
treatment
the
with
porcine
Myers
associated.
quantitative in
confluent-serum
in serum-rich
bovine
COMMUNICATIONS
in 10% FBS.
As expected ester
have
quiescent
instance,
10% FBS was membrane
in
RESEARCH
PKC immunofluorescence
incubated
in confluent
ratio
ratios
sparse,
growing
BIOPHYSICAL
is in agreement
activity
and in
actively
activity
in which
Similar
cells
the
AND
the
In
control
nuclei
were
(PMA) resulted PKC. In contrast
perinuclear
staining
Vol.
in
189,
No.
PMA-treated
activity
BIOCHEMICAL
1, 1992
3T3-Ll
cells
was associated
using
only
with
AND
BIOPHYSICAL
a polyclonal nonnuclear
RESEARCH
antibody
COMMUNICATIONS
to
membranes
PKG. However,
and not
with
the
PKC
nuclear
fraction. affect and
The
exact
role
the
transcription
interferon
proteins
PKC in
been
and only
systems,
envelope.
nucleus
PMA-stimulated reported,
II
some of Thus,
these
the
is
not
including
yet
lamin
(19). proteins,
B (16),
such
Phorbol
plasminogen of
Most of these
physiological
known.
c-fos,
phosphorylation
including
and DNA topoisomerase
nuclear
the
of many genes,
(17).
has
proteins
of
studies
as lamin
PKC nuclear
activator
a variety histones used B,
are
esters
of
nuclear
(18),
matrix
reconstitution located
substrates
in
have
not
the been
identified. In that
BAEC express
treatment
of
membrane areas.
the
present
PKC a and
EC results
fractions, Further
isoenzymes insights
in
summary,
in to the
in
the
multiple
we provide
I3 isotypes,
but
immunocytochemical not
y.
translocation
of
PKC activity
a and 13 isoforms
of
PKC appear
understanding response
study
of
to
different
regulatory
the
intracellular agonists effects
phorbol
from to
location and
of
Although
antagonists
evidence
the
ester
cytosol
shift
to
different
of
the
different
to
may contribute
PKC.
REFERENCES
1. Nishizuka, Y.. (1988) Nature 334: 661-665. 2. Blackshear P.J. (1988) Am. J. Med. Sci. 296: 231-240. 3. Myers, C.L., J.S. Laze, B.R. Pitt. (1989) Am. J. Physiol. 257: L253-L258. 4. Bruns R.F., Miller F.D., Merriman R.L., Howbert J.J., Heath W.F., Kobayashi E ., Takahashi I., Tamaoki T., Nakano H. (1991) Biochem Biophy Res Comm 176:288293. 5. Bradford, M.M. (1976) Anal. Biochem. 72:248-254. 6. Kraft, A.S., W.B. Anderson, H.L. Cooper, J.J. Sando. (1982) J. Biol. Chem. 257: 13193-13196. 7. Hidaka, H., T. Tanaka, K. Onoda, H. Ohta, M. Watanabe, Y. Itoh, M. Tsurudone, K. Izutsu, T. Yoshida. (1988) J. Biol. Chem. 263: 4523-4526. 8. Leach, K.L., E. A. Powers, J.C. McGuire, L. Dong, S. Jaken. (1988) J. Biol. Chem. 263: 13223-13230. 9. Wilson, T. (1990) Confocalmicroscopy. pp 325-335. Academic Press, San Diego, 10. Halsey, D.L., P.R. Girard, J. F. Kuo, P.J. Blackshear. (1987) J. Biol. Chem. 262: 2234-2243. 11. Uratsuji, Y., P.E. DiCorleto. (1988) J. Cell Physiol. 136: 431-438. 12. Shoji, M., P.R. Girard, G.J. Mazzei, W.R. Vogler, J.F. Kuo. (1986) Biochem. Biophys. Res. Commun. 135: 1144-1149. 13. Ito, T., T. Tanaka, T. Yoshida, K. Onoda, H. Ghta, M. Hagiwara, Y. Itoh, M. Ogura, H. Saito, H. Hidaka. (1988) J. Cell Biol. 107: 929-937. 14. Jaken, S., K. Leach, T. Klauck. (1989) J. Cell Biol. 109: 697-704. L. Cheever, H. Khaner, P.C. Simpson. (1990) 15. Mochly-Rosen D., C.J. Henrich, Cell Regulation 1: 693-706. 16. Hocevar, B.A., A.P. Fields. (1991) J. Biol. Chem. 266: 28-33. V.A. Ruff, S. Jaken, S. Kaufmann. (1989) J. Cell 17. Leach, K.L., E.A. Powers, Biol. 109: 685-695. 18. Butler, A.P., G.V. Byus, T.J. Slaga.(1986) J. Biol. Chem. 261: 9421-9425. 19. SaLyoun, N., M. Wolf, J. Besterman, T.S. Hsieh, P. Cuatrecasas. (1986) Proc. Natl. Acad. Sci. USA. 83: 1603-1607.
46