Actin Directly Interacts with Phospholipase D,
Inhibiting Its Activity*
Sukmook
Lee,
Jong Bae
Park,
Jong Hyun
Kim,
Yong
Kim
,
Jung Hwan
Kim,
Kum-Joo
Shin,
Jun Sung
Lee,
Sang Hoon
Ha,
Pann-Ghill
Suh, and
Sung Ho
Ryu§
From the Division of Molecular and Life Sciences, Pohang University
of Science and Technology, Pohang 790-784, Republic of Korea
Received for publication, September 18, 2000, and in revised form, May 22, 2001
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ABSTRACT |
Mammalian phospholipase D (PLD) plays a key role
in several signal transduction pathways and is involved in many diverse
functions. To elucidate the complex molecular regulation of PLD, we
investigated PLD-binding proteins obtained from rat brain extract. Here
we report that a 43-kDa protein in the rat brain, 
-actin, acts as a
major PLD2 direct-binding protein as revealed by peptide mass fingerprinting in combination with matrix-assisted laser desorption ionization/time-of-flight mass spectrometry. We also determined that
the region between amino acids 613 and 723 of PLD2 is required for the direct binding of -actin, using bacterially expressed glutathione S-transferase fusion proteins of PLD2
fragments. Intriguingly, purified -actin potently inhibited both
phosphatidylinositol-4,5-bisphosphate- and oleate-dependent
PLD2 activities in a concentration-dependent manner
(IC50 = 5 nM). In a previous paper, we reported
that 
-actinin inhibited PLD2 activity in an
interaction-dependent and an ADP-ribosylation factor 1 (ARF1)-reversible manner (Park, J. B., Kim, J. H., Kim, Y.,
Ha, S. H., Kim, J. H., Yoo, J.-S., Du, G., Frohman, M. A., Suh, P.-G., and Ryu, S. H. (2000) J. Biol.
Chem. 275, 21295-21301). In vitro binding analyses
showed that -actin could displace -actinin binding to PLD2,
demonstrating independent interaction between cytoskeletal proteins and
PLD2. Furthermore, ARF1 could steer the PLD2 activity in a positive
direction regardless of the inhibitory effect of -actin on PLD2. We
also observed that -actin regulates PLD1 and PLD2 with similar
binding and inhibitory potencies. Immunocytochemical and
co-immunoprecipitation studies demonstrated the in vivo
interaction between the two PLD isozymes and actin in cells. Taken
together, these results suggest that the regulation of PLD by
cytoskeletal proteins, -actin and -actinin, and ARF1 may play an
important role in cytoskeleton-related PLD functions.
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INTRODUCTION |
Mammalian phospholipase D
(PLD)1 hydrolyzes
phosphatidylcholine (PC) to generate phosphatidic acid and choline in
response to a variety of signals, which can include hormones,
neurotransmitters, and growth factors (1). phosphatidic acid itself has
been shown to be an intracellular lipid second messenger and to be
involved in multiple physiological events such as the promotion of
mitogenesis, stimulation of respiratory bursts, secretory processes,
actin cytoskeletal reorganization, and the activation of Raf-1 kinase and phosphatidylinositol 4-phosphate (PtdIns4P) 5-kinase isoforms in a
large number of cells. These relationships suggest that agonist-induced PLD activation may play roles in multiple signaling events (2-7).
The mammalian PLD isozymes identified thus far, PLD1 and PLD2, share a
sequence homology of ~50%, but they have very different regulatory
properties. PLD1 has low basal activity in the presence of
phosphatidylinositol-4,5-bisphosphate (PIP2) and can be
activated by several cytosolic factors including protein kinase C and small GTP-binding proteins such as Rho A, Rac-1, ARF1, RalA, and CDC42 (8-15). PLD2 also depends on PIP2 but has a higher
basal activity than PLD1 (16), and it has been proposed that PLD2 may
be closely associated with different cellular inhibitors. Although many
studies continue to focus on the functional relationships and the
isozyme specificities of the PLD isozymes, the molecular mechanism of
the regulation of the PLDs has not been fully elucidated. In this
regard, the identification of PLD-binding partners may provide clues
toward the understanding of the complex regulatory mechanism of PLD in
different cells.
It has been observed in many studies that PLD is crucially implicated
in the actin-based cytoskeleton of cells. More recently, PLD activity
has been found in the detergent-insoluble fraction of various cell
types that contain a wide range of cytoskeletal proteins (17-18).
Several cytoskeletal proteins such as fodrin and gelsolin have been
found to act as PLD-specific inhibitors in vitro (19-21),
and agonist-induced PLD stimulation can provoke changes in cell
morphology through cytoskeletal rearrangement (5, 22-24). Furthermore,
we reported previously that -actinin, an F-actin cross-linking
protein, also binds to PLD2 to inhibit its activity (25). Thus, there
is a strong body of evidence supporting a possibly close regulatory
association between PLD and the actin cytoskeleton.
In our present study, we found for the first time that -actin,
a major cytoskeletal protein, negatively regulates PLD by direct
binding. We also looked at the relationships and modes of action of
ARF1 and other cytoskeletal proteins on PLD using PLD2 as a model
enzyme, and the results obtained suggest possible mechanisms for
the regulation of PLD by these cellular components.
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EXPERIMENTAL PROCEDURES |
Materials--
The enhanced chemiluminescence kit (ECL system),
dipalmitoylphosphatidyl-[methyl-3H]choline,
chelating-Sepharose, DEAE-Sepharose, and Sephadex-150 resin were
purchased from Amersham Pharmacia Biotech.
Dipalmitoyl-phosphatidylcholine, PIP2,
dioleoyl-phosphatidylethanolamine, paraformaldehyde, and sodium oleate
were purchased from Sigma. Anti-actin antibody was purchased from ICN
Pharmaceuticals. GTP
S was obtained from Roche Molecular
Biochemicals. Horseradish peroxidase-conjugated goat anti-rabbit
IgG and goat anti-mouse IgA, IgM, and IgG were from Kirkegaard & Perry
Laboratories (Gaithersburg, MD). Dulbecco's modified Eagle's medium
was purchased from Life Technologies, Inc. Immobilized protein A and
fluorescein isothiocyanate-conjugated goat anti-rabbit antibody were
purchased from Pierce. -octylglucopyranoside was obtained from
Calbiochem. Rhodamine-phalloidin was obtained from Molecular Probes. A
polyclonal antibody that recognizes both PLD1 and PLD2 was generated as
described previously (25). Anti-ARF monoclonal antibody was provided
kindly by Dr. Richard A. Kahn (Emory University, Atlanta, GA).
Full-length cDNAs of murine PLD2 and its N-terminal deletion mutant
were provided generously by Dr. Michael A. Frohman (State University of
New York, NY).
Purification of Recombinant PLD from Baculovirus-transfected
sf9 Cells--
Hexa-histidine (His6)-tagged PLD1
and PLD2 were purified from detergent extracts of baculovirus-infected
sf9 cells by chelating-Sepharose affinity column chromatography
as described previously (26).
Preparation of Rat Brain Extract--
Rat brains (3 g) were
homogenized in homogenation buffer (20 mM Tris/HCl, pH 7.5, 1 mM MgCl2, 1 mM EDTA, 1 mM EGTA, and 150 mM NaCl) using a polytron
homogenizer. After centrifugation at 100,000 × g for
1 h at 4 °C, the resulting supernatant was used to investigate
potential PLD2-binding partners. Protein concentrations in the brain
extract were determined using the methods developed by Bradford
(27).
Co-precipitation of PLD2-binding Proteins--
Affinity-purified
anti-PLD antibodies immobilized on protein A resin (PLD antibody
complex) were first incubated with purified recombinant PLD2 (3 µg)
for 2 h. After a brief centrifugation, the immune complexes were
washed three times with radioimmune precipitation buffer (50 mM Tris/HCl, pH 8.5, 0.1% SDS, 150 mM NaCl,
1% TX-100, and 1% deoxycholate). The prepared brain extract (3 mg of
protein) was then incubated with the complexes for 2 h at 4 °C.
Finally, the co-precipitated proteins were washed again three times
with radioimmune precipitation buffer, loaded onto a gel, and
visualized by Coomassie Brilliant Blue staining.
Identification of a 43-kDa Protein Using Peptide Mass
Fingerprinting by Matrix-assisted Laser Desorption
Ionization/Time-of-Flight Mass Spectrometry--
The technique used
was performed as described previously (25). In brief, the fraction
containing 43-kDa protein (p43) after co-immunoprecipitation from rat
brain extract was separated by 8% SDS-PAGE, and the band corresponding
to p43 was excised and digested with trypsin (Roche Molecular
Biochemicals) for 6 h at 37 °C. The masses of the
tryptic peptides obtained were determined with a Voyager DE
time-of-flight mass spectrometer (Perceptive Biosystems, Inc.,
Framingham, MA) in the Korea Basic Science Institute. Delayed ion
extraction resulted in peptide masses with better than 50 ppm mass
accuracy on average. Using the amino acid sequences and the mass
numbers of the tryptic peptides of p43, the Swiss-Prot data base was
searched for a protein match.
Purification of -Actin and ARF1--
-actin was purified
from rat brain as described previously (28) and assessed to be >90%
pure by Coomassie staining. Myristoylated recombinant ARF1 was
expressed in Escherichia coli and purified (29).
Construction and Preparation of GST Fusion Proteins--
The
full-length cDNA of human PLD2 was digested into fragments
containing specific domains. These individual PLD2 fragments were then
ligated into the EcoRI or SmaI site of the
pGEX4T3 vector. Human -actin cDNA, kindly provided by Dr.
Jungchul Kim (Kyungpook National University, Korea), was then ligated
into the EcoRI site of the pGEX4T1 vector (Amersham
Pharmacia Biotech). Subcloning and the polymerase chain reaction were
used to produce the expression vectors encoding the respective GST
fusion proteins (30). E. coli BL21 cells were transformed
with individual expression vectors encoding the GST fusion proteins,
and after harvesting the cells the GST fusion proteins expressed were
purified by standard methods (31) using glutathione-Sepharose 4B
(Amersham Pharmacia Biotech).
In Vitro Binding Analysis--
All operations were performed at
4 °C in a refrigerated room or on ice. The two recombinant PLD
isozymes prepared or COS-7 cell extracts overexpressing wild type and
the N-terminal deletion mutant of murine PLD2 (
1-185) were first
bound to PLD antibody complexes. These were then respectively incubated
with the indicated amounts of purified -actin or ARF1 for 15 min at
37 °C. At this stage, all of the PLD-binding partners were present
in the PLD assay buffer (50 mM HEPES/NaOH, pH 7.3, 3 mM EGTA, 3 mM CaCl2, 3 mM MgCl2, and 80 mM KC1) containing
0.5% -octylglucopyranoside. After brief centrifugation, the
co-precipitated complexes were washed three times in the same buffer
before being loaded onto a polyacrylamide gel. The in vitro
binding of the GST-PLD2 fragments with -actin was also performed in
the same buffer containing 1% TX-100. All procedures using -actinin
binding were similar to those used for -actin binding. In brief,
PLD2 immune complexes were incubated with -actinin and -actin at
37 °C for 15 min in the PLD assay buffer, and the resulting
co-precipitates were washed with the same buffer containing 0.25%
CHAPS as described previously (25).
PLD Activity Assay--
PIP2-dependent
PLD activity was assayed by measuring choline release from
phosphatidylcholine (12) with minor modifications. In brief, the
reaction was carried out at 37 °C for 15 min in a 125-µl assay
mixture containing the PLD assay buffer, the PLD preparation, and 25 µl of phospholipid vesicles composed of
dioleoyl-phosphatidylethanolamine, PIP2,
dipalmitoyl-phosphatidylcholine, and
dipalmitoyl[methyl-3H]choline (a total of
150,000 cpm/assay) in a molar ratio of 16:1.4:1. Oleate-dependent PLD activity was assayed as described
earlier (26). In brief, PC vesicles (25 µl) containing 5 nmol of
dipalmitoyl-phosphatidylcholine and 200,000 dpm of
dipalmitoylphosphatidyl-[methyl-3H]choline
were added to a reaction mixture (175 µl) containing 50 mM HEPES/NaOH, pH 7.0, 2 mM EGTA, 1.7 mM CaCl2, 20 µM sodium oleate,
and 0.1 M KCl. The final concentration of PC in the
reaction mixture was 25 µM. The assay mixture was then
incubated at 30 °C for 1 h, and the reaction was terminated by
the addition of 0.3 ml of 1 N HCl/5 mM EGTA and
1 ml of chloroform/methanol/HCl (50:50:0.3). After a brief
centrifugation, the amount of
[methyl-3H]choline in 0.5 ml of the aqueous
phase was quantified by liquid scintillation counting.
Immunoblot Analysis--
Proteins were denatured by boiling for
5 min at 95 °C in a Laemmli sample buffer (32), separated by
SDS-PAGE, and transferred to nitrocellulose membranes by
electroblotting using the Bio-Rad wet transfer system. After blocking
in TTBS buffer (10 mM Tris/HCl, pH 7.5, 150 mM
NaCl, and 0.05% Tween 20) containing 5% skim milk powder, the
membranes were incubated with individual monoclonal or polyclonal
antibodies, which was subsequently followed by another incubation with
anti-mouse or anti-rabbit IgG, as required, coupled with horseradish
peroxidase. Detection was performed using an enhanced chemiluminescence
kit according to manufacturer instructions.
Cell Culture--
The tetracycline-regulated (Tet-off)
expression system (Life Technologies, Inc.) was used to induce the
expression of PLD2 in PC12 cells (33). Clonal cell lines were
maintained in Dulbecco's modified Eagle's medium supplemented with
0.5 µg/ml tetracycline, 10% (v/v) equine serum, and 5% fetal calf
serum. To induce PLD2, the cells were grown in the same medium without
tetracycline. COS-7 cells were maintained in a growth medium composed
of Dulbecco's modified Eagle's medium supplemented with 10% fetal
bovine serum at 37 °C in a humidified CO2-controlled
(5%) incubator. For transfection and the transient expression of PLD
isoforms, COS-7 cells were plated at a density of 1 × 106 cells/well in 100-mm dishes and transfected using
LipofectAMINE (Life Technologies, Inc.) as described previously
(34).
Co-immunoprecipitation--
PLD2-inducible PC12 cells cultured
in the presence or absence of tetracycline or COS-7 cells
overexpressing PLD1 were lysed with PLD assay buffer containing 1%
cholate, 1% TX-100, 1 mM phenylmethylsulfonyl fluoride, 1 µg/ml leupeptin, and 5 µg/ml aprotinin. After brief sonication, the
cell lysates were incubated for 2 h with constant agitation and
centrifuged at 100,000 × g for 1 h. The cell
extracts (1 mg of protein) recovered were incubated with anti-PLD
antibody-immobilized on protein A resin for 2 h. After brief
centrifugation, the co-immunoprecipitated complexes were washed three
times with ice-cold radioimmune precipitation buffer before being
loaded onto a polyacrylamide gel for immunoblot analysis.
Preparation of COS-7 Cell Membranes--
Cells transfected with
the wild type and the N-terminal deletion mutant of murine PLD2
(1-185) were disrupted by sonication in ice-cold PLD assay buffer.
The lysates were then centrifuged at 100,000 × g for
1 h at 4 °C, and the pellet was resuspended in the same buffer
and referred to as membranes.
Immunocytochemistry--
Immunocytochemistry was performed as
described previously (35). In brief, PC12 cells grown on coverslips in
the presence or absence of tetracyclin were rinsed with PBS four
times and fixed with 3.7% (w/v) paraformaldehyde for 10 min at
37 °C. After rinsing with PBS and blocking with PBS containing 1%
goat serum and 0.1% TX-100 for 4 h at 4 °C, the cells were
incubated with 2 µg/ml primary polyclonal antibody specific to PLD
overnight at 4 °C. The cells were washed six times with PBS
containing 0.05% TX-100 and then incubated in this washing medium with
fluorescein isothiocyanate-labeled goat anti-rabbit secondary antibody
and rhodamine-phalloidin for 1 h to visualize PLD2 and filamentous actin (F-actin), respectively. To visualize F-actin in COS-7 cells overexpressing GFP, GFP-PLD1, or GFP-PLD2 (36), they were incubated with rhodamine-phalloidin as described above. Slides were then examined
under a fluorescence microscope (Nikon, Melville, NY).
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RESULTS |
The 43-kDa Protein Precipitated with PLD2 from a Rat Brain Extract
Was Identified as -Actin--
Because the regulation of PLD could
possibly occur through direct interaction between PLD and other binding
partners, we started our investigation by looking for cellular
PLD2-binding proteins from rat brain extract using purified PLD2
complexed with anti-PLD antibody. After the precipitation (PLD2
precipitate) and protein analysis by SDS-PAGE, we found that the
co-precipitate contained major PLD2-binding proteins with relative
molecular masses of 48 (p48), 43 (p43), and 35 kDa (p35) and
some minor proteins. As shown in Fig. 1,
these bands appeared in distinctive patterns only in PLD2
immunoprecipitates. A major band corresponding to p43 in the PLD2
precipitates was excised from the gel for identification by peptide
mass fingerprinting. A trypsinized peptide mixture of p43 was then
subjected to matrix-assisted laser desorption ionization/time-of-flight
mass spectrometry. Fig. 2A
shows the matrix-assisted laser desorption ionization mass spectrum of
the digested peptides of p43. The masses obtained, marked as P1-P7, were compared with proteins in the Swiss-Prot data base using the
MS-Fit peptide mass search program. As shown in Table
I, the peptides exhibited molecular
masses that were almost identical to the calculated masses of the
corresponding theoretically predicted tryptic peptides of -actin.
The accuracy of this peptide search result was obtained with 50 ppm,
and the analyzed peptides covered 21% of the -actin sequence
(Table. I). To substantiate the identity of this protein further, the
presence of actin in the PLD2 precipitate was confirmed using a
monoclonal antibody to actin. As shown in Fig. 2B, actin was
strongly detected in the PLD2 precipitate but not in a control immune
complex. On the basis of these results, we concluded that the 43-kDa
protein in the PLD2 precipitate from the rat brain extract was
-actin.
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Fig. 1.
Co-immunoprecipitation of PLD2-binding
proteins from rat brain extracts. Anti-PLD antibody complexes in
the absence ( ) or presence (+) of recombinant PLD2 were incubated
with homogenation buffer (MOCK) or rat brain extract
(EXT) as described under "Experimental Procedures."
After the isolation of the precipitates, the proteins were resolved by
SDS-PAGE and visualized by Coomassie Blue staining. The PLD2-binding
protein with a molecular mass of 43 kDa is indicated by an
arrow. The results shown are representative of three
separate experiments.
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Fig. 2.
Identification of p43 as
-actin. A, p43 isolated from
proteins that co-precipitated with PLD2 was digested with trypsin, and
the resulting peptide mixture was analyzed by matrix-assisted laser
desorption ionization/time-of-flight mass spectrometry. The
arrows indicate matched peaks among the measured tryptic
peaks of p43 with calculated molecular masses of -actin within 50 ppm. P1-P7, the molecular masses of the peptides
obtained. B, equal aliquots of the
co-immunoprecipitates used in Fig. 1 were separated by SDS-PAGE and
analyzed by immunoblot analysis using antibodies directed against PLD
or actin, respectively. The lane order is the same as that described in
the Fig. 1 legend.
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Table I
Peptide sequences and masses from p43 by matrix-assisted laser
desorption ionization/time-of-flight mass spectrometry
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-Actin Directly Associates with a Region (Amino Acids 613-723)
of PLD2--
To determine whether -actin associates directly with
PLD2, -actin from rat brain was purified to over 90% (data not
shown) using the methods of Bray and Thomas (28) and incubated with the
PLD2-bound immune complexes. As shown in Fig.
3A, the resulting co-precipitation demonstrated that -actin interacts directly with
PLD2. To identify the PLD2 sequence involved in the -actin binding,
we constructed the GST fusion proteins shown in Fig. 3B and
tested them for their ability to bind to purified -actin. GST-PLD2
(amino acids 613-723) was found to be the region that most potently
bound to -actin (Fig. 3C). It seems therefore that the
region of the protein encoded between amino acids 613 and 723 may be
important for the direct interaction with -actin.
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Fig. 3.
Direct interaction of
-actin with PLD2. A, Anti-PLD
antibody complexes were first incubated in the absence () or presence
(+) of purified PLD2. After three washings with ice-cold radioimmune
precipitation buffer, the complexes were incubated with purified
-actin (30 nM) as described under "Experimental
Procedures." After precipitation, the samples were subjected to
immunoblot analysis. B, PLD2 cDNA was fragmented into
individual domains consisting of F1 (1-314),
F2 (315-475), F3
(476-612), F4 (613-723),
F5 (724-825), and F6
(826-934). The fragments were cloned as GST fusion
proteins, expressed in E. coli, and purified using
glutathione-Sepharose beads. Boxes are the regions of highly
conserved sequences in PLD. PX, phox; PH,
pleckstrin homology; I-IV, conserved regions I-IV;
CT, C-terminal region. C, equal amounts (1 µg)
of GST or GST fusion proteins (GST-PLD2 fragments, F1-F6)
were incubated with purified -actin (150 nM) as
described under "Experimental Procedures." The precipitated
proteins were subjected to immunoblot analysis using antibodies
directed against actin (upper panel). GST was used as the
control. The amounts of the GST fusion proteins were visualized on the
nitrocellulose membrane by Ponceau staining (lower panel).
The results shown are representative of two separate experiments.
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-Actin Specifically Inhibits PLD2 Activity in Vitro--
We
monitored PLD activity to determine the effect of -actin on PLD2. As
shown in Fig. 4A, the
PIP2-dependent activity of PLD2 was inhibited
specifically in a -actin concentration-dependent manner.
Using -actin purified from rat brain, the concentration required for
half-maximal inhibition was about 5 nM. To further confirm
the inhibitory effect of -actin on PLD2 activity, we constructed and
purified a GST--actin for reconstitution assays of PLD activity. As
expected, we observed that this GST--actin had an inhibitory effect
that was similar to that of the -actin purified from rat brain. To
exclude the possibility that the -actin-inhibited PLD2 activity
might be caused by PIP2 sequestration or masking in the
substrate phospholipid vesicles, we also performed a PLD2 activity
assay in the absence of PIP2. We previously reported that
PLD2 could be activated specifically by oleate (18:1) in the absence of
PIP2 (26). As shown in Fig. 4B, PLD2 activated by oleate was inhibited progressively by increasing either the concentration of -actin purified from rat brain or GST--actin with similar inhibitory potency. The inhibitory efficacy of -actin, under the condition of the oleate assay, was close to that observed under the condition that included PIP2 (Fig.
4A). Taken together, these results suggest that the
inhibitory effect of -actin on PLD2 might be mediated by direct
interaction.
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Fig. 4.
-actin-induced PLD2 inhibition
in vitro. A, The
PIP2-dependent activity of PLD2 was measured
for 15 min in a PIP2-dependent assay mixture in
the presence of GST ( ), GST--actin ( ) from E. coli,
or purified -actin ( ) from rat brain as described under
"Experimental Procedures." The results are expressed as a
percentage of the control (basal PLD2-induced choline release). The
data are the means ± S.D. of three different experiments
performed in duplicate. B, oleate-dependent PLD
activity was measured in the presence of 20 µM sodium
oleate at 30 °C for 1 h as described under "Experimental
Procedures," and the concentration of GST (), GST--actin ()
from E. coli, or purified -actin () from rat brain was
varied as indicated. The data represent the means ± S.D. obtained
from two separate experiments performed in duplicate.
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-Actin and -Actinin Act Independently on PLD2 in a Reversible
Manner--
In a previous study, we found that -actinin binds
directly to the N-terminal region (amino acids 1-185) of PLD2 and
inhibits activity of the enzyme (25). To clarify the relationship
between the two cytoskeletal proteins, -actin and -actinin, in
terms of PLD2 binding, in vitro binding assays were
performed. Fig. 5A
demonstrates that an increase in -actin reduced -actinin binding
to PLD2 in a competitive and concentration-dependent
manner. In other words, the binding of -actin to PLD2 induced the
release of -actinin already bound to PLD2. To exclude the
possibility that this mode of competition occurs through the same
binding site on the two proteins, we used an N-terminal -actinin
binding region deletion mutant of PLD2 (PLD2 (1)). In
vitro binding analysis showed that -actin binds to PLD2
(1) with an affinity comparable with that of wild-type PLD2 (Fig.
5B), proving that -actin does not bind to the -actinin
binding region of PLD2. To further substantiate this mode of
competition, we also performed a PLD activity assay and compared the
inhibitory effects of -actin on wild type and PLD2 (1). As
shown in Fig. 5C, -actin potently inhibited the activities of both PLD2 (1) and wild type to similar extents. These results indicate that -actin may inhibit PLD2 activity by
interacting directly with a site other than the -actinin binding region and suggest further that -actin and -actinin act
independently on PLD2 in a reversible manner.
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Fig. 5.
Effect of -actin on
the interaction and regulation of -actinin
with PLD2. A, PLD2 (0.1 µg)-bound PLD immune
complexes were incubated with -actinin (267 nM) and the
indicated amounts of -actin under PLD assay conditions at 37 °C
for 15 min. After a brief centrifugation, the precipitates were washed
as described under "Experimental Procedures" and subjected to
immunoblot analysis. PLD2, -actinin, and -actin were detected
using antibodies to PLD, -actinin, or actin, respectively. The data
shown here represent one of two separate experiments. B,
COS-7 cells were transfected with the empty vector (MOCK),
N-terminal 185-amino acid-truncated PLD2
(PLD2(1-185)) or wild-type PLD2
(PLD2). After the preparation of PLD immune complexes, these
complexes were incubated with 30 nM of -actin as
described under "Experimental Procedures." The final
co-precipitates were subjected to immunoblot analysis. The results
shown are representative of two separate experiments. C,
COS-7 cell membranes overexpressing N-terminal 185-amino acid-truncated
PLD2 (PLD2(1-185),  ) or wild-type PLD2
(PLD2, ) were prepared as described under "Experimental
Procedures" and used as a source of PLD2. PLD activity was determined
with 0.3 µg of membrane in the presence of various concentrations of
-actin purified from rat brain. The data represent the means ± S.D. obtained from two separate experiments performed in
duplicate.
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-Actin-inhibited PLD2 Activity Can Be Activated by
ARF1--
This study was undertaken to determine whether the
repression of PLD2 activity by -actin could be modulated by cellular
factors. Previously, we had reported that the -actinin inhibited
PIP2-dependent PLD2 activity could be
completely restored by ARF1 and that this recovery was caused by the
release of -actinin from PLD2 by ARF1 binding (25). Therefore, we
studied the effect of ARF1 in this system by increasing the
concentration of ARF1 in the PLD activity assay in the presence and
absence of 30 nM purified -actin. As shown in Fig.
6A, -actin strongly
inhibited PIP2-dependent PLD2 activity, this
inhibition could be activated by varying the concentration of ARF1, and
this was independent of the effect of -actin to PLD2. It was
suspected that this simple activation may not be caused by competition
but by different forms of binding between PLD2 and ARF1 or -actin.
To further elucidate the mode of action of ARF1 on the actin-PLD
interaction, we added ARF1 in the presence of PLD2 and -actin. Fig.
6B shows that even though the amount of ARF1 was increased
to 3.2 µM in the presence of GTPS, ARF1 expectedly did
not compete out any PLD2-bound -actin. Taken together, these results
suggest that -actin might bind to PLD2 independently of ARF1 and
that -actin-induced PLD2 inhibition might be regulated by a mode of
action of ARF1 that differs from that of -actinin.
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Fig. 6.
Effect of ARF1 on
-actin-induced PLD2 inhibition. A,
the PIP2-dependent PLD activity was measured in
the absence () or presence () of 30 nM purified
-actin as described under "Experimental Procedures," and the
amounts of GTPS-stimulated ARF1 were varied as indicated. The data
represent the means ± S.D. of three separate experiments in
duplicate. B, the same amounts of PLD2 (0.1 µg)-bound
immune complex were incubated with 60 nM purified
-actin. ARF1 was then added in increasing amounts in the presence of
10 µM GTPS, and the incubation continued at 37 °C
for 15 min under PLD assay conditions. After the precipitation and
washing step, the final precipitates were subjected to immunoblot
analysis. PLD2, -actin, and ARF1 were detected using PLD-, actin-,
or ARF-specific antibodies, respectively. The results shown are
representative of three separate experiments performed using
independent preparations.
|
|
PLD2 Specifically Interacts and Co-localizes with the Actin
Cytoskeleton in PC12 Cells--
The possibility that actin may
interact with PLD2 inside the cell was tested by using a
co-immunoprecipitation method on PLD2-overexpressing PC12 cells, which
are able to induce the expression of PLD2 upon tetracycline withdrawal
(33). As shown in Fig. 7A, a
very low level of PLD2 was expressed in PC12 cells in the presence of
tetracycline, which we considered representative of the level of
endogenous PLD2. Actin did co-immunoprecipitate with PLD2 from extracts
of the PLD2-overexpressing PC12 cells cultured in the absence of tetracycline, demonstrating a specific interaction between actin and
PLD2 in vivo. In these cells, the overexpression of PLD2 did not affect the endogenous expression of actin (data not shown). To
further check whether PLD2 co-localized with the actin cytoskeleton in
PC12 cells, the PLD2-overexpressing PC12 cells were stained immunofluorescently with the anti-PLD antibody. As shown in Fig. 7B, the overexpressed PLD2 was found to be localized near
the plasma membrane of the PC12 cells, and co-staining of filamentous actin with rhodamine-phallodin showed that the PLD2 co-localized with
F-actin in the PC12 cells. Taken together, these results suggest that
actin regulation of PLD2 might occur through direct interaction within
the actin cytoskeleton regions.
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|
Fig. 7.
Specific interaction of PLD2 with the actin
cytoskeleton in PC12 cells. A, PC12 cells cultured in
the absence or presence of tetracycline were lysed and sonicated in
extraction buffer containing 1% TX-100 and 1% cholic acid as
described under "Experimental Procedures." After centrifugation,
the resulting supernatants (1 mg) were incubated with the anti-PLD
antibody complex followed by immunoblot analysis using PLD- or
actin-specific antibodies. The results were reproducible in
three experiments performed with independent preparations.
B, PLD2-inducible PC12 cells cultured in the absence () or
presence (+) of tetracyclin were fixed and stained with the anti-PLD
antibody and then incubated with fluorescein isothiocyanate-conjugated
goat anti-rabbit IgG and rhodamine-phalloidin as described under
"Experimental Procedures." The arrowheads point to
regions in which PLD2 and F-actin overlap. The results shown are
representative of two separate experiments.
|
|
-Actin Inhibits PLD1 as well as PLD2 in an
Interaction-dependent Manner--
Mammalian PLD has two
isozymes, PLD1 and PLD2, that have a sequence homology of ~50%. To
check the effect of purified -actin on these two PLD isozymes,
in vitro binding analysis was performed. Fig.
8A shows that -actin
interacted directly with both PLD isozymes with almost the same
affinity. To further check the inhibitory effect of -actin on PLD
isozymes, we reconstituted purified -actin and PLD isozymes in a PLD
activity assay in the presence of ARF1. In this case, we measured the
activity of both PLD isozymes activated by ARF1 to compare the effect
of -actin under the same conditions. Fig. 8B shows that
-actin similarly inhibited PLD1 and PLD2 activity in a
concentration-dependent manner. To determine whether actin also forms a complex with PLD1 in vivo, we transfected a
vector containing PLD1 in COS-7 cells. The cell extracts were subjected to co-immunoprecipitation and immunoblot analysis. As shown in Fig.
8C, actin immunoreactivity was detected not in
immunoprecipitates of the vector-transfected cells but in those of the
PLD1-transfected cells, showing that actin associates tightly with PLD1
in cells. We also confirmed, in these cells, that actin was
co-immunoprecipitated with PLD2 as was shown in PC12 cells (data not
shown). To further examine the interaction between PLD isozymes and the
actin cytoskeleton in cells, we transfected GFP, GFP-PLD1, or GFP-PLD2
into COS-7 cells. As shown in Fig. 8D, F-actin co-localized
with the two PLD isozymes, which suggests an association between PLD
and the actin cytoskeleton. Taken together, these results suggest that -actin may inhibit the activities of both PLD isozymes through direct interaction in these cells.
View larger version (18K):
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|
Fig. 8.
The effect of -actin
on PLD isozymes. A, the same amounts (0.1 µg) of PLD1
and PLD2-bound immune complexes were incubated with 50 nM
of -actin as described under "Experimental Procedures." After
the precipitation and washing steps, the final co-precipitates were
subjected to immunoblot analysis. PLD1, PLD2, and actin were detected
using anti-PLD or actin antibodies. The results represent one of two
experiments performed with independent preparations. B,
purified PLD1 () and PLD2 () activated by ARF1 were assayed to
determine the concentration-dependent effect of -actin
on PLD isozymes as described under "Experimental Procedures." The
concentration of purified -actin was varied as indicated. The assays
also contained 10 µM GTPS. The results shown represent
the means ± S.D. from three different experiments performed in
duplicate. C, COS-7 cells were transfected with empty vector
(Vec) or pCDNA 3.1 vectors encoding PLD1 as described
under "Experimental Procedures." The total amount of vector DNA used per transfection was 5 µg. The
transfected cells were lysed, extracted, and co-immunoprecipitated with
polyclonal PLD antibody as described under "Experimental
Procedures." Final PLD immune complexes were subjected to immunoblot
analysis and the bands were detected with antibodies to PLD or actin.
The results shown are representative of two separate experiments.
D, COS-7 cells overexpressing GFP, GFP-PLD1, or GFP-PLD2
were grown on coverslips and stained as described under "Experimental
Procedures" to visualize F-actin. The arrowheads point to
candidate regions in which the two PLD isozymes and F-actin overlap.
The results shown are representative of two separate experiments.
|
|
| |
DISCUSSION |
Although some evidence exists that suggests that PLD activity is
confined to the cytoskeletal fraction and may be involved closely in
actin cytoskeletal rearrangement in vivo, the regulatory mechanism of PLD involvement in the actin cytoskeleton has remained obscure. Thus, we decided to conduct a parallel study of possible PLD-binding proteins that could be linked to the regulation of PLD. In
this paper, we used PLD2 as a model enzyme and investigated PLD2-binding proteins using a co-immunoprecipitation method with rat
brain extracts. As a result, -actin, a major component of the
cytoskeleton, was identified as a PLD2-binding protein and further
found that direct interaction between -actin and PLD2 inhibits the
activity of the enzyme. In addition, through reconstitution experiments
involving -actin, -actinin, and/or ARF1 together with PLD2 we
found a possible mode of action for the regulation of the PLD complex
by cytoskeletal proteins and ARF1.
PLD2 is constitutively active in vitro. However, it has been
proposed that it may interact with some cellular inhibitors in vivo. In the present paper, we report for the first time that -actin directly interacts with PLD2 and specifically inhibits its
activity (Figs. 3A and 4). Several lines of evidence support the notion that actin may have a role as an inhibitor by interacting with PLD2. First, purified -actin inhibits PLD2 at a very low concentration (in the nanomolar range) (Fig. 4A). Second,
-actin-induced PLD2 inhibition is not caused by other factors such
as protease in the purified actin fraction (data not shown). Third,
GST--actin also inhibits PLD2 activity in a manner similar to
purified -actin (Fig. 4A). Fourth, the inhibitory
activity of -actin on PLD2 is relatively unaffected by the presence
or absence of PIP2 (Fig. 4B). These results
suggest that the inhibition by -actin is not caused by
PIP2 sequestration or masking. We also confirmed that the
PLD2 inhibition is not reversible by increasing the PIP2
concentration (data not shown). At present, various PLD inhibitors are
classified as cytoskeleton-related proteins such as fodrin,
-actinin, and gelsolin (19-21, 25, 37) and vesicle
trafficking-related proteins such as amphiphysin, -/-synuclein,
synaptojanin, and clathrin assembly protein 3 (31, 38-40). It has been
suggested that fodrin and synaptojanin may sequester or hydrolyze
PIP2 to suppress PLD activity, whereas assembly protein 3 and -actinin might inhibit PLD activity through direct interaction.
In summary, the data available to date suggest that diverse and
function-related PLD inhibitors may regulate PLD by different
mechanisms in different cells.
-Actin binds directly to a region between amino acids 613 and 723 of
PLD2 (Fig. 3C). This region does not contain the putative phosphoinositide binding sites of PLD2 such as the N-terminal pleckstrin homology domain (41) or the conserved basic amino acids
(42). On the contrary, this -actin-binding region of PLD2 contains
the conserved region III that seems critically important for PLD
function, and it has been suggested that this region might be involved
in the interaction between PLD and the choline headgroups of PC
(43-45). Thus, -actin binding to this region may inhibit the
interaction of PLD2 with its substrates and thus inhibit the rate of
their catalysis. More specifically, the direct interaction between
-actin and PLD2 may be essential to maintain the repression of PLD2
activity in nascent cells.
The actin cytoskeleton is a highly dynamic network composed of actin
polymers and a large variety of associated proteins (46-47). In recent
papers, PLD activity has been reported in the detergent-insoluble fraction of HL-60 and U937 cells (17-18), demonstrating the
possibility of in vivo interaction between PLD and the
actin-based cytoskeleton. It has been further suggested that several
F-actin-binding proteins such as fodrin and -actinin act as
PLD-specific inhibitors in vitro (19-20, 25). However,
there had been no report that has proved an in vivo
interaction between PLD2 and the actin cytoskeleton. Therefore, our
immunocytochemical study is the first study to demonstrate that PLD2 is
localized near the plasma membrane of PLD2-overexpressing PC12 cells
(as has been reported previously in other cells (24)) and that it is
co-localized with filamentous actin (Fig. 7B). Moreover, our
co-immunoprecipitation results also show a specific interaction between
PLD2 and the actin cytoskeleton in PC12 cells (Fig. 7A).
Therefore, our results suggest that the actin cytoskeleton may be
associated closely with and possibly involved in the regulation of PLD2.
In this study, we tried to develop a possible model for the complex
regulatory mechanisms operating between the cytoskeletal proteins,
ARF1, and PLD2. Our findings show that -actin uses a binding site
(amino acids 613-723) on PLD2, which differs from that used by
-actinin and ARF1. It seems that ARF1 does not share either an
identical or an overlapping binding site with -actin on PLD2. As
reported previously, -actinin interacts with the N-terminal region
(amino acids 1-185) of PLD2, and it seems that ARF1 can induce the
release of -actinin from PLD2 by causing a conformational change in
the enzyme (25). However, the regulatory mode of the -actin-induced
PLD2 inhibition by ARF1 must differ from its regulation of
-actinin-induced inhibition. Therefore, we suggest that the
regulation of PLD2 by -actin or -actinin occurs via different
binding sites on PLD2, that they may occur independently, and that they
may be activated by different modes of action of ARF1. Our observation
that the binding/inhibitory capacity of -actin to PLD2 is almost
similar in both wild type and N-terminal deletion mutant, -actinin
binding region (1-185), further supports the notion that -actin
and -actinin use different binding sites and perhaps act by inducing
conformational changes. We also suggest that the independent
interaction between the two cytoskeletal proteins and PLD2 is
probably not caused by an interaction between -actin and
-actinin, because the interaction between -actin, another actin
muscle isoform, and -actinin have been reported to be very weak
(Kd = 2 µM) (48) and because we found
that GST--actin did not bind to -actinin under the same
conditions (data not shown). Therefore, our findings lead to the
possible speculations that PLD2 may exist in various populations, its
regulation by either -actin or -actinin may change according to
the spatial and temporal conditions in the cells, and that this would
be reflected in a different responsiveness to ARF1. We suggest that the
complex mechanisms involved in the regulation of PLD2 by cytoskeletal
proteins may be related to the actin cytoskeletal changes required when
cells are stimulated by diverse signals.
ARF plays a major role in the regulation of PLD (49-51) in various
cell types, and it also may be involved in actin cytoskeletal rearrangements in these cells. It has been reported recently that ARF1
stimulates wild-type human PLD2 a little less than 2-fold, whereas an N-terminal deletion (1) mutant of PLD2 was stimulated about 13-fold in vitro (16, 52). In HIRcB cells, insulin
activated PLD2 by a mechanism sensitive to brefeldin A (6). PLD, ARF, GRP1, and ARNO (guanine-nucleotide exchange factors with specificity for ARF) exist in the detergent-insoluble fraction of several cell
types (17-18, 54-55), and ARF1 also potentiated Rho-stimulated stress
fiber formation in Swiss 3T3 fibroblasts (56). Our finding that the
inhibition of PLD2 by -actin can be activated by ARF1 (Fig.
6A) further supports the hypothesis that ARF1 may be an important factor in the regulation of PLD2. Although we concentrated on
the effect of ARF1 on the regulation of PLD2, we cannot exclude the
possibility that ARF6 may be implicated in both the regulation of PLD2
and the actin cytoskeletal changes in cells. Increasing numbers of
reports have shown that ARF6 can activate rat brain PLD (57) or plasma
membrane-associated PLD in chromaffin cells (58). Furthermore, Honda
et al. (7) reported that ARF6 co-localizes with PLD2 in
membrane rufflings upon treatment with epidermal growth factor.
All these observations suggest that various ARF proteins might be
deeply involved in the complex mechanism of the regulation of PLD2 in
the actin cytoskeleton.
The mammalian PLD isozymes, PLD1 and PLD2, have a sequence homology of
over 50% and are found in highly conserved regions in the PLD
superfamily (53, 59). Although many previous reports have suggested
that the two PLD isozymes may exhibit different regulatory properties,
one interesting possibility arises from the observation that -actin
interacts with and inhibits both PLD isozymes with similar potency
in vitro (Fig. 8, A and B). This
suggests that actin may have a broad interaction and regulation spectrum for PLD in cells. This is supported further by our result that
actin was co-immunoprecipitated and co-localized with two PLD isozymes
in COS-7 cells. On the basis of our results, we also suggest that
conserved region III, the -actin binding region of PLD2, may
contribute to the interaction and regulation of the two PLD isozymes.
Although this needs further detailed work, many reports support this
suggestion because this region is highly conserved in PLD family
members that exhibit bona fide PLD activity. Furthermore, we
suggest that the regulation of PLD by the actin cytoskeleton may depend
on -actin binding to this conserved region III of PLD in cells.
In summary, we have identified one of the PLD-binding proteins as
-actin and found that direct interaction between -actin and PLD
specifically mediates PLD activity. On the basis of our results, we
suggest that the close association between the actin cytoskeleton and
PLD may inhibit PLD activity in nascent cells. Upon stimulation by
appropriate agonists, the translocation of ARF to the membrane may
activate the repressed activity of PLD by the actin cytoskeleton. In
the future, we hope to study the details and fine-tuning of this
regulatory mechanism in the actin cytoskeleton.
| |
FOOTNOTES |
*
This work was supported by POSTECH Research Initiative
Program and the programs of the National Research Laboratory of the Ministry of Science and Technology and the Center for Cell Signaling Research in the Republic of Korea.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
To whom correspondence should be addressed. Tel.: 82-54-279-2292;
Fax: 82-54-279-2199; E-mail: sungho@ postech.ac.kr.
§
Present address: Laboratory of Molecular and Cellular Neuroscience,
Rockefeller University, 1230 York Ave., New York, NY
10021-6399.
Published, JBC Papers in Press, May 23, 2001, DOI 10.1074/jbc.M008521200
| |
ABBREVIATIONS |
The abbreviations used are:
PLD, phospholipase
D;
PC, phosphatidylcholine;
PIP2, phosphatidylinositol-4,5-bisphosphate;
ARF, ADP-ribosylation factor;
GTPS, guanosine 5'-3'-O-(thio) triphosphate;
TX-100, Triton X-100;
PAGE, polyacrylamide gel electrophoresis;
GST, glutathione S-transferase;
CHAPS, 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid;
PC12, pheochromocytoma;
GFP, green fluorescent protein.
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