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From the
Received for publication, March 27, 2002, and in revised form, June 25, 2002
We showed previously that protein kinase C (PKC)
is required for phagocytosis of apoptotic leukocytes by murine alveolar
(AMø) and peritoneal macrophages (PMø) and that such phagocytosis is markedly lower in AMø compared with PMø. In this study, we examined the roles of individual PKC isoforms in phagocytosis of apoptotic thymocytes by these two Mø populations. By immunoblotting, AMø expressed equivalent PKC Phagocytosis, the uptake of large particles (>0.5 µm) via
actin-dependent mechanisms (1), is the obligatory means of
clearing apoptotic cells during development and in resolving
inflammation (2). Only macrophages can efficiently clear the large
numbers of apoptotic leukocytes produced during waning immune responses (3-6). Indeed, the efficiency of this process is evidenced by the fact
that apoptotic cells are rarely observed in vivo (7); one
exception is in the lungs of mice, where apoptotic lymphocytes are
easily demonstrable both in health and inflammation (8). This defect in
clearance is consistent with the finding that the principal resident
lung phagocytes, alveolar macrophages
(AMø),1 exhibit markedly
lower capacity for phagocytosis of apoptotic leukocytes, either
compared with inflammatory lung Mø (in rabbits) (9) or with resident
peritoneal Mø (PMø) (in mice) (10). In the latter system, no
disparity between AMø and PMø was detected using three other particle
types (10, 11). Murine AMø also exhibited a relative deficit in
phagocytosis of apoptotic cells in vivo (10). We have
recently found that human AMø also show much lower phagocytosis of
apoptotic cells than of other particles in
vitro.2 Contrasting the
properties of these two types of resident tissue Mø could aid in
defining the molecular basis of apoptotic cell recognition, which is
poorly understood.
Recognition of apoptotic cells is initiated through at least two
pathways. Using a 70-kDa glycosylated type II transmembrane protein
called PS-R' (12), Mø and other cell types recognize externalized
phosphatidylserine (PS), which translocates from the inner to the outer
leaflet of the cell membrane early in apoptosis (13-17). Recognition
of externalized PS has been suggested to be both necessary and
sufficient to generate a signal for ingestion (13, 18). More recently,
the Mø-specific receptor tyrosine kinase Mer has been identified as
critical for the phagocytosis of apoptotic cells by murine Mø (19).
How signaling from these two receptors leads to apoptotic cell
phagocytosis is undefined. A host of other Mø cell surface receptors
(reviewed in Ref. 20) have also been implicated in clearance of
apoptotic cells, but they appear to be involved principally in adhesion
rather than in recognition of cell death (21). Moreover, although we
(10) and others (22) have identified a number of differences in
expression of adhesion molecules between murine AMø and PMø, blocking
experiments using monoclonal antibodies (mAbs) or the
arginine-glycine-aspartic acid-serine (RGDS) tetrapeptide have not
supported any identified adhesion receptor, including several
integrins, as being responsible for the functional difference in
phagocytosis (10).
An alternative explanation for disparity between Mø types in apoptotic
cell phagocytosis would be differences in postreceptor signal
transduction. A logical candidate for such a difference is protein
kinase C (PKC), because we and others have shown that it is required
for apoptotic cell clearance (11, 23). PKC comprises a family of
related serine/threonine kinases divided into three groups on the basis
of structure and cofactor requirements (24). Activation of PKC requires
phosphorylation on serines/threonines, displacement of its
autoinhibitory pseudosubstrate domain, and translocation to specific
cytoskeletal and intracellular membrane sites of action (25).
Activation of the conventional group (cPKC) ( We recently showed (11) that phagocytosis of apoptotic thymocytes by
murine AMø and PMø was reduced by the nonspecific PKC inhibitor
staurosporine and by Gö 6976 but only incompletely by calphostin
C. Gö 6976 has been reported to act as a partially selective
inhibitor of the cPKC Reagents--
Rottlerin and Ro-32-0432 were purchased from
Calbiochem. PMA, PBS, RPMI 1640, fetal bovine serum, HEPES, pyruvate, 1 kb Plus brand up markers and penicillin/streptomycin were obtained from Invitrogen. Dimethyl sulfoxide, dexamethasone,
2-mercaptoethanol, sodium deoxycholate, glycerol, NaCl, Tris-HCl,
Triton X-100, Tween 20, 1 kb Plus brand up markers,
L- Mice--
All experiments were performed using pathogen-free
C57BL/6 female mice purchased from Charles River Laboratories Inc.
(Wilmington, MA) at 7-8 weeks of age and used at 8-14 weeks of age.
Mice were housed in the Animal Care Facility at the Ann Arbor VA
Medical Center, which is fully accredited by the American Association for Accreditation of Laboratory Animal Care. This study complied with
the National Institutes of Health "Guide for the Care and Use of
Laboratory Animals" (Department of Health, Education, and Welfare
Publication No. 80-32) and followed a protocol approved by the Animal
Care Subcommittee of the local institutional review board.
Isolation and Culture of Mø--
Mice were euthanized by
asphyxia in a high CO2 environment, which we have
previously shown does not impair the capacity of AMø to ingest
apoptotic thymocytes (10). Resident AMø and PMø were harvested and
cultured as previously described (10). Mø were isolated by adherence
onto tissue culture plates (for protein isolation) or eight-well
Lab-Tek slides (for phagocytosis assay) for 2-4 h at 37 °C in 5%
CO2 in complete medium (RPMI 1640 containing 10%
heat-inactivated fetal bovine serum, 25 mM HEPES, 2 mM L-glutamine, 1 mM pyruvate, 100 units/ml penicillin/streptomycin, 55 µM
2-mercaptoethanol). Nonadherent cells were removed by gentle washing.
In experiments in which PKC localization was analyzed by Western
blotting, complete medium was replaced with serum-free medium for
1 h.
Preparation of Apoptotic Thymocytes--
Thymuses were harvested
from normal mice and minced to yield a single cell suspension. To
induce apoptosis, thymocytes were resuspended in complete medium to a
concentration of 1 × 106 cells/ml and incubated for
6 h in complete medium containing 1 µM
dexamethasone. This treatment yields a population with a low percentage
(mean 13.4%) contamination of late apoptotic or necrotic cells (10,
11).
Western Analysis of PKC Isozymes--
Resident AMø and PMø
from normal mice were isolated and plated at 1.0 × 106 cells/ml on 100 × 15-mm plates in medium
containing 10% serum and incubated for 2 h at 37 °C and 5%
CO2. Next, Mø were washed and solubilized in ice-cold
lysis buffer consisting of 1.0% Triton X-100, 20 mM
Tris-HCl, pH 8.0, 150 mM NaCl, 0.1% SDS, 0.5% sodium deoxycholate, and 10% glycerol with protease inhibitors (complete minitablet) and phosphatase inhibitor mixture II (1:100) for 30 min on
ice. After sonicating for 3 s and centrifuging at 13,800 × g for 3 min, 7 µg of protein/sample was run on a 10%
acrylamide gel under reducing conditions and transferred to a
polyvinylidene difluoride membrane using 25 mM Tris, 192 mM glycine, 20% methanol. Blots were blocked with 5%
nonfat dry milk in PBS (blocker), incubated with the appropriate
anti-PKC isoform antibody (1:1000 dilution in blocker), and washed five
times for 5 min each with PBS containing 0.1% Tween 20. Blots were
incubated with horseradish peroxidase-conjugated goat anti-rabbit IgG
(diluted 1:10,000 in PBS containing 5% nonfat dry milk), and the
chemiluminescence signal was developed by adding a
peroxidase/luminol-based substrate (Supersignal Femto reagent; Pierce).
The identity of PKC isoforms on Western blots was verified using
isoform-specific blocking peptides. No bands were seen when blots were
stained using horseradish peroxidase-conjugated goat anti-rabbit IgG alone.
To analyze the subcellular distribution of PKC isozymes, Mø were
isolated and plated at 1.0 × 106 cells/ml on 30 × 15-mm plates in medium containing 10% serum and incubated
for 2 h at 37 °C and 5% CO2. The medium was then removed and replaced with serum-free medium for 1 h followed by washing and scraping in cold PBS. Next, Mø were sonicated for 10 s in 50 mM Tris, pH 8.0, 9 mM EDTA and then
centrifuged at 100,000 × g for 45 min. The supernatant
was collected and defined as the cytosolic fraction. The pellet,
defined as the membrane and cytoskeleton fractions, was solubilized in
ice-cold lysis buffer (defined above) for 30 min on ice. This
solubilized pellet fraction was sonicated for 3 s and then
centrifuged at 13,800 × g for 3 min. Equal amounts of
protein (3-7 µg) were run on a 10% SDS-PAGE gel under reducing
conditions, transferred to the polyvinylidene difluoride membrane, and
stained as described above.
Preparation of Liposomes--
To produce liposomes, PS or the
negatively charged control lipid PI was dried under N2 and
resuspended in serum-free medium by vortexing. Liposome size was
determined by Coulter counter analysis to be in a similar range as
apoptotic thymocytes, 2-3.2 µm. In these experiments, Mø were
incubated for 1 h in serum-free medium, liposomes in serum-free
medium were added to Mø monolayers in a final PS or PI
concentration of 0.11 mM, and Mø and liposomes were
co-incubated for the indicated time at 37 °C and 5%
CO2. Cells were washed and scraped in cold PBS; sonicated
for 10 s in 50 mM Tris, pH 8.0, 9 mM EDTA;
and centrifuged at 100,000 × g for 45 min.
RNA Preparation and Reverse Transcriptase-PCR--
Total RNA was
isolated from adherent AMø and PMø using TRIzol (Invitrogen). Reverse
transcriptase-PCRs were performed using kits from Invitrogen. The
primer sets used were the following: for mouse PS-R'
(GenBankTM accession number AF304118), forward CTC ACG ATG
AAC CAC AAG AGC and reverse GGA CCA GCC CTC TTG TGC ATT; for mouse
glyceraldehyde-3-phosphate dehydrogenase (GenBankTM
accession number M32599), forward GGT CGG TGT GAA CGG ATT TGG and
reverse ATG AGG TCC ACC ACC CTG TTG. The expected PCR product sizes are
245 bp for PS-R' and 968 bp for glyceraldehyde-3-phosphate dehydrogenase. PCR products were analyzed on a 2% agarose gel and
stained with ethidium bromide. The identity of the target products was
confirmed by sequencing.
Flow Cytometric Analysis--
Apoptosis was measured by
simultaneous annexin V and propidium iodide staining (apoptosis
detection kit; R & D Systems, Minneapolis, MN) according to the
manufacturer's protocol. Cells were analyzed without fixation by flow
cytometry within 1 h of staining. Staining of surface receptors
and flow cytometry were performed as previously described in detail
(33) using a FACScan cytometer (BD PharMingen) running Cell Quest
software on a PowerPC microcomputer (Apple, Cupertino, CA) for data
collection and analysis. A minimum of 10,000 cells were analyzed.
Phagocytosis Assay--
Phagocytosis of apoptotic thymocytes
in vitro was assayed by co-incubation of 0.5-2.0 × 105 adherent Mø with 2.0 × 106 apoptotic
thymocytes for 90 min at 37 °C in 5% CO2 as previously described (10). Results are expressed as the percentage of Mø containing at least one ingested thymocyte (percentage of phagocytosis) and as the phagocytic index, which was generated by multiplying the
percentage of phagocytosis by the mean number of ingested cells per
Mø. Cell-permeable PKC inhibitors were added either 30 min (rottlerin)
or 18 h (Ro-32-0432 and PMA) before the addition of apoptotic
thymocytes. Myristoylated PKC peptides from the carboxyl terminus of
the V5 region of PKC Adhesion Assay--
Adherence of apoptotic thymocytes to Mø
in vitro was assayed in the same fashion as phagocytosis,
except that 2 × 107 apoptotic thymocytes suspended in
400 µl of complete medium were added to each well, yielding a 100:1
ratio of thymocytes to Mø. The slides were incubated for various times
at 37 °C and then washed in a standardized fashion by dipping
individual slides five times in each of two Wheaton jars filled with
ice-cold PBS. Slides were then stained using hematoxylin-eosin Y
(Richard-Allan; Kalamazoo, MI) and coverslipped. Adhesion was evaluated
by counting 200-300 Mø per well at ×1000 magnification
under oil immersion and scoring for bound thymocytes. Results are
expressed as the percentage of Mø binding at least one thymocyte
(percentage of adhesive Mø) and as the adhesion index, which was
generated by multiplying the percentage of adherence-positive Mø by
the mean number of adherent thymocytes per Mø. In blocking
experiments, mAbs were used at concentrations previously determined to
be saturating by flow cytometry, and culture supernatant containing mAb
217 was concentrated 10-fold using Centriprep tubes (Amicon, Bedford, MA).
Statistical Analysis--
Data are expressed as mean ± S.E. Statistical calculations were performed using Statview on a
Macintosh Power PC G3 computer. Continuous ratio scale data were
evaluated by unpaired Student's t test (for two
samples) or analysis of variance (for multiple comparisons) with
post hoc analysis by the Tukey-Kramer test or by the
two-tailed Dunnett test, which specifically compares treatment groups
with a control group (35). Use of these parametric statistics was
deemed appropriate, since phagocytosis of apoptotic thymocytes by PMø
has been shown to follow a Gaussian distribution (36). Significant
differences were defined as p < 0.05.
AMø Express Lower Amounts of Most PKC Isoforms than Do
PMø--
Western blot analysis using PKC isoform-specific antibodies
demonstrated markedly lower expression of PKC Effect of Overnight PMA Treatment on Mø Phagocytosis of Apoptotic
Thymocytes--
Chronic (18-h) PMA treatment depletes cPKCs and nPKCs
but not aPKCs, with the degree to which individual isoforms are
affected depending on the cell type and the PMA concentration (27,
37-39). In preliminary experiments, the concentration and time of PMA addition were optimized to achieve maximal inhibition of apoptotic cell
phagocytosis. We determined that the conditions used were nontoxic, as
indicated by assay of lactate dehydrogenase release.2
Western blot analysis on AMø and PMø after overnight treatment using
8.1 µM PMA confirmed that PKC Rottlerin and Ro-32-0432 Decrease Phagocytosis of Apoptotic
Thymocytes at Concentrations at Which They Inhibit
cPKCs--
To further define which PKC isoforms are essential for
phagocytosis, we used two cell-permeable PKC inhibitors, rottlerin and Ro-32-0432, which show a degree of isoform specificity. Rottlerin specifically inhibits PKC Myristoylated PKC
We found that the myristoylated PKC PS Liposomes Stimulate Translocation of PKC Isoforms
We found that PS liposomes strongly stimulated translocation of PKC
Resident Murine Mø Express the Stereo-specific PS-R', Which
Mediates PKC Translocation in Response to PS Liposomes--
These data
raised the question of whether the stereo-specific PS-R' identified by
Fadok and associates (12) could contribute to PKC activation
during Mø recognition of apoptotic cells. Expression of PS-R' was
detected by multiple methods in both types of Mø. Reverse
transcriptase-PCR demonstrated equivalent PS-R' mRNA in AMø and
PMø (Fig. 8A). Flow cytometry
showed distinct surface expression of PS-R' by both types of Mø (Fig.
8, B and C). Although specific staining and
background staining of both Mø types varied slightly between
experiments, mean channel fluorescence of PMø was generally somewhat
higher than that of AMø (e.g. in the experiment shown in
Fig. 8, mean channel fluorescence was 484.7 for PMø versus 161.4 for AMø). Hence, the absence of PS-R' expression by AMø did not
appear to explain our previous finding of decreased phagocytosis of
apoptotic cells (10).
To determine whether PS-R' was functional on both types of Mø, we
performed phagocytosis and adhesion assays in the presence of the
blocking mAb 217. Blockade of PS-R' specifically and profoundly inhibited phagocytosis of apoptotic thymocytes (Fig.
9, A and B), in
agreement with previous data using this mAb on other cell types (12).
However, the same concentration of mAb 217 had no effect on adhesion of
apoptotic thymocytes to either type of Mø (Fig. 9, C and
D). These data confirm that both AMø and PMø express functional PS-R' but that this receptor does not mediate apoptotic cell
adhesion.
To determine whether stimulation via PS-R' induced PKC activation, we
tested whether mAb 217 could inhibit PS liposome-induced translocation
of PKC The principal findings of this study indicate that PKC The finding that PKC PKC That phagocytosis of apoptotic targets might involve unique signal
transduction elements should not be surprising. In contrast to the
proinflammatory responses activated by phagocytosis via other pathways
(1), phagocytosis of apoptotic cells is continuous during development
and antiphlogistic during resolving inflammation (62-65). The finding
that murine thioglycollate-elicited PMø secreted MIP-2/CXCL2 upon
ingestion of apoptotic T cells has been interpreted as a contradiction
to this principle (66), but an alternative view would be that
production of this chemokine in the absence of other proinflammatory
signals simply recruits Mø as part of the beneficial clean-up process.
Ingestion of apoptotic T cells has been found to compromise Mø host
defense functions in vivo (67). Hence, we speculate that the
relatively deficient phagocytosis of apoptotic leukocytes by AMø
may be a beneficial evolutionary adaptation. Even moderate suppression
of chemokine and monokine secretion in the lungs may tip the balance in
favor of virulent pathogens such as enteric Gram-negative bacteria and
Staphylococcus aureus or may be sufficient to permit evasion
of innate immunity by less virulent pathogens such as anaerobes.
Our current data showing that both murine AMø and PMø respond to PMA
agrees with the preponderance of results in other systems. Heale and
Speert (68) found that PMA can reverse the inability of murine AMø to
ingest Pseudomonas aeruginosa. Although Peters-Golden et al. (69) initially reported that PMA caused release of
arachidonic acid in a PKC-dependent manner in rat PMø but
not AMø, a more recent paper from that group showed that the
augmentation of Fc Our analyses of PS-R' advance the understanding of this receptor's
role in the process of apoptotic cell clearance. The gene for this
receptor has been conserved with exceedingly high fidelity across
greater than 600 million years of evolution between organisms as
disparate as Caenorhabditis elegans, Drosophila
melanogaster, and mammals (12). This conservation and the fact
that it was not previously identified by genetic analysis of C. elegans mutants (which suggests that its deletion may be lethal)
speaks to its fundamental importance. Because we show that mAb 217 does
not block adhesion, the PS-R' function must depend on initial adhesion via other receptors. Thus, it is a recognition molecule that imparts specificity to the interaction. We cannot at present exclude the possibility that only those AMø that express high amounts of surface PS-R' participate in phagocytosis. However, the fact that only roughly
40% of PMø showed significant staining, yet virtually all PMø ingest
apoptotic cells in an annexin V-inhibitable fashion (10), urges caution
in interpretation of flow cytometry data using mAb 217. The high
background staining seen using this IgM mAb precludes accurate
definition of the lower limit of expression, and even small amounts of
PS-R' may be sufficient. In addition to the stereo-specific PS-R', PS
can be bound by multiple receptors including class B scavenger
receptors, CD14, macrosialin (CD68), and
thrombospondin-dependent vitronectin receptors (1,
71-73).
The demonstration that resident murine AMø express lesser amounts of
multiple PKC isoforms, compared with resident Mø at another body
surface, further highlights the distinctive differentiation of this
cell type (74, 75). AMø appear to have evolved as specialized
phagocytes whose principal task is to keep the gas-exchanging surface
of the alveoli clear yet not compromised by excessive inflammation.
AMø have a mostly suppressive role on the induction of adaptive immune
responses within the lung itself (76, 77), permitting local expression
of T cell effector functions while inhibiting their proliferation (78).
Indeed, AMø differ from other Mø types in expression of surface
receptors (79, 80), in antigen-presenting capacity (81), and in
eicosanoid production (82, 83). Our results agree with previous studies
that found markedly lower expression of multiple PKC isoforms,
including PKC In summary, these data demonstrate for the first time that Mø
phagocytosis of apoptotic cells requires PKC We thank Dr. Lilli Petruzzelli and all of the
members of the Ann Arbor Veterans Affairs Medical Center Research
Enhancement Award Program for helpful suggestions, Dr. Valerie Fadok
for the generous gift of mAb 217, and Joyce O'Brien for secretarial support.
*
This work was supported by United States Public Health
Service Grants RO1 HL56309 and RO-1 HL6157, Merit Review funding, and a
Research Enhancement Award Program grant from the Department of
Veterans Affairs. Portions of this work have been presented previously
at the Autumn Immunology Conference, Chicago, IL, November 17, 2001, and at the American Thoracic Society Meeting in Atlanta, GA, May 22, 2002.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: Pulmonary and Critical
Care Medicine Section (506/111G), Dept. of Veterans Affairs Medical
Center, 2215 Fuller Rd., Ann Arbor, MI 48105-2303. Tel.: 734-761-7980;
Fax: 734-761-7843; E-mail: jlcurtis@umich.edu.
Published, JBC Papers in Press, July 11, 2002, DOI 10.1074/jbc.M202967200
2
J. C. Todt, B. Hu, A. Punturieri, J. Sonstein, T. Polak, and J. L. Curtis, unpublished observation.
The abbreviations used are:
AMø, alveolar macrophage(s);
aPKC, atypical PKC isoform;
cPKC, conventional PKC
isoform;
DAG, diacylglycerol;
mAb, monoclonal antibody;
Mø, macrophage(s);
nPKC, novel PKC isoform;
PI, phosphatidylinositol;
PKC, protein kinase C;
PMø, peritoneal macrophages;
PMA, phorbol
12-myristate 13-acetate;
PS, phosphatidylserine;
PBS, phosphate-buffered saline;
RACK, receptor for activated C kinase.
Activation of Protein Kinase C
II by the Stereo-specific
Phosphatidylserine Receptor Is Required for Phagocytosis of Apoptotic
Thymocytes by Resident Murine Tissue Macrophages*
,,§,,, and§¶
**
Division of Pulmonary and Critical Care
Medicine, Department of Internal Medicine, the ¶ Comprehensive
Cancer Center, and the Graduate Program in Immunology,
University of Michigan Health Care System and the
§ Pulmonary and Critical Care Medicine Section, Medical
Service, Department of Veterans Affairs Care System,
Ann Arbor, Michigan 48105-2303
ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
but lower amounts of other isoforms (
,
I, II, 
, 
, µ, and 
), with the greatest difference in II expression. A requirement for PKC II for phagocytosis was demonstrated collectively by phorbol 12-myristate 13-acetate-induced depletion of PKC II, by dose-response to PKC inhibitor Ro-32-0432, and by use of PKC II myristoylated peptide as a blocker. Exposure of
PMø to phosphatidylserine (PS) liposomes specifically induced translocation of PKC II and other isoforms to membranes and
cytoskeleton. Both AMø and PMø expressed functional PS receptor,
blockade of which inhibited PKC II translocation. Our results
indicate that murine tissue Mø require PKC II for phagocytosis of
apoptotic cells, which differs from the PKC isoform requirement
previously described in Mø phagocytosis of other particles, and imply
that a crucial action of the PS receptor in this process is PKC II activation.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
, I, II, and 
)
is calcium- and diacylglycerol (DAG)-dependent. Activation
of the novel group (nPKC) (, , , and 
) also depends on
binding of DAG, but it is calcium-independent. The atypical group
(aPKC) (
/
and ) cannot be activated by calcium or DAG. All PKC
family members bind PS on the cytosolic leaflet of the cell membrane,
but aPKCs require additional incompletely defined lipid activators
(24). Another isoform, PKC µ (often called PKD in the mouse), does
not fit into any of the major groups. PKC µ contains two unique
hydrophobic domains in its amino terminus and is
phospholipid-dependent but calcium-insensitive (26). Individual cell types usually express several PKC isoforms, each of
which appears to mediate unique functions (27). Even the 50-amino acid
difference in the alternatively spliced forms of PKC (I and
II) appears to be responsible for the unique role of each PKC isozyme (28, 29). Thus, differences between murine AMø and PMø in PKC
isoform expression or function could explain the functional difference
between these two cell types in apoptotic cell phagocytosis.
and I isoforms (30), whereas calphostin C
has greater activity against nPKCs than cPKCs (31). However, current
data on the specificity of these inhibitors are too inconclusive (32)
to allow us to predict with certainty which isoforms are involved.
Therefore, in this study, we used six approaches to further define the
PKC isoform(s) involved in Mø phagocytosis of apoptotic thymocytes.
First, because the pattern of PKC isoforms in primary murine tissue Mø
has not been described, we analyzed PKC isoform expression using
isotype-specific antibodies and Western blotting. Second, we tested the
effect of overnight exposure of Mø to phorbol 12-myristate 13-acetate
(PMA), which depletes cPKC and nPKC isoforms by interacting with their
DAG-binding sites, on AMø and PMø phagocytosis of apoptotic
thymocytes. Third, we employed the isoform-selective inhibitors,
rottlerin and Ro-32-0432. Fourth, we tested the effect of myristoylated
blocking peptides against PKC I, PKC II, and PKC on
phagocytosis of apoptotic thymocytes by AMø and PMø. Fifth, we
examined the effect of PS liposomes, as models for apoptotic
thymocytes, on translocation of PKC isoforms to cell membranes and
cytoskeleton; apoptotic thymocytes could not be used, because they
themselves express multiple PKC isoforms. Finally, we studied Mø
expression of PS-R' and the relationship between PS-R' stimulation and
PKC translocation. Collectively, our results indicate a requirement for
PKC II in Mø phagocytosis of apoptotic thymocytes, show that an
antibody against PS-R' blocks translocation of PKC II in response to
PS liposomes, and suggest that relative deficiency of PKC II and possibly other PKC isoforms may partially explain the functional difference in apoptotic cell clearance by AMø.
EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-phosphatidylinositol (PI), L--PS, and
phosphatase inhibitor mixture II were purchased from Sigma. Antibodies
and blocking peptides for PKC isoforms and horseradish peroxidase-conjugated anti-rabbit IgG were purchased from Santa Cruz
Biotechnology, Inc. (Santa Cruz, CA). Complete mini-protease inhibitor
tablets and the lactate dehydrogenase cytotoxicity detection kit were
purchased from Roche Molecular Biochemicals. SDS, 0.2-µm polyvinylidene difluoride membrane, nonfat dry milk blocker, and 10%
Ready Acrylamide gels were obtained from Bio-Rad. Supersignal West
Femto Maximum Sensitivity substrate was obtained from Pierce. Eastman
Kodak Co. X-Omat AR film and eight-well Lab-Tek slides were obtained
from Fisher. mAb 217 (anti-murine PS-R; rat IgM) was generously
provided by Dr. Valerie Fadok (National Jewish Medical Center, Denver,
CO) as a culture supernatant; in selected experiments, a commercial
preparation of this mAb (Cascade BioScience, Winchester, MA) was used.
Myristoylated PKC peptides were synthesized by
BIOSOURCE Quality Controlled Biochemicals
(Hopkinton, MA) at 90% purity, as confirmed by high pressure liquid
chromatography and mass spectroscopy performed by the manufacturer.
(myr-PQFVHPILQSAV-amide), PKC I
(myr-DQNEFAGFSYTNPEFVINV-amide), or PKC II
(myr-SFVNSEFLKPEVKS-amide) were added to a final concentration of 100 µM 30 min before the addition of apoptotic thymocytes.
The myristate moieties coupled to the amino terminus of these peptides
allow membrane permeability, permitting their use in primary cells
(34). All inhibitors were nontoxic at the times and concentrations
utilized, as determined by the lactate dehydrogenase cytotoxicity
detection kit.2
RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
, I, II, ,
, µ, and 
in resident murine AMø in comparison with resident
murine PMø (Fig. 1). By contrast, AMø
had slightly higher expression of PKC . Staining did not detect
expression of PKC or PKC in either murine AMø or
PMø,2 in agreement with previous analyses of human tissue
Mø (24, 37), and we did not test expression of the lymphocyte-specific isoform PKC . Thus, the lower expression of several PKC isoforms by
AMø is a potential explanation for the previously observed decreased
phagocytosis of apoptotic cells by this cell type.
View larger version (30K):
[in a new window]
Fig. 1.
Resident murine AMø and PMø differ in
expression of multiple PKC isoforms. Whole cell lysates of AMø
and PMø of normal C57BL/6 mice cultured as adherent monolayers for
2 h were analyzed for expression of PKC isoforms by Western
blotting using isoform-specific antibodies.
, I, II, and were significantly depleted (p < 0.05, unpaired
t test) by PMA treatment in either of the two types of Mø
(Fig. 2). As anticipated, PKC , ,
µ, and were not depleted by overnight PMA treatment in either Mø type. In the functional assay, the same overnight PMA treatment significantly decreased phagocytosis by AMø and PMø
(p < 0.05, unpaired Student t test) (Fig.
3). Control experiments showed that
overnight PMA treatment did not influence adhesion of thymocytes to
PMø (percentage of adhesive Mø, 86.1 ± 1.7% (control)
versus 82.0 ± 2.0% (PMA-treated), p = 0.16; adhesion index, 2.6 ± 0.2 (control) versus
2.7 ± 0.1 (PMA-treated); mean ± S.E., n = 4, p = 0.47, both comparisons made by unpaired
t test) and actually slightly increased adhesion to AMø
(adhesive Mø, 60.5 ± 1.5% (control) versus 71.5 ± 2.2% (PMA-treated); mean S.E., n = 4;
p < 0.001; adhesion index, 1.2 ± 0.1 (control)
versus 1.7 ± 0.0 (PMA-treated); p < 0.001, unpaired t test). Collectively, these data indicate that the nPKC isoforms and , the aPKC isoform , and PKC
µ/PKD are not essential for Mø phagocytosis of apoptotic cells
but leave open the question of which cPKC or other nPKC isoforms are
required.
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Fig. 2.
Overnight PMA treatment decreases expression
of cPKC and nPKC isoforms by AMø and PMø. Resident AMø and PMø
were incubated overnight at 37 °C and 5% CO2 with
either PMA (8.1 µM final concentration) or the
appropriate amount of ethanol as the control and then analyzed for
expression of PKC isoforms by Western blotting using isoform-specific
antibodies.
View larger version (14K):
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Fig. 3.
Depletion of cPKCs and nPKCs by overnight PMA
treatment reduces Mø phagocytosis of apoptotic thymocytes.
Phagocytosis of apoptotic thymocytes by resident AMø and PMø
incubated overnight in medium containing a final concentration of 8.1 µM PMA (black bars) or the
appropriate amount of ethanol as a control (gray
bars) was determined by examining hematoxylin-eosin
Y-stained slides under oil immersion. A, percentage of
phagocytic Mø; B, phagocytic index. Data are mean ± S.E. of four replicates in two experiments. *, p < 0.05, unpaired Student's t test.
at relatively low concentration
(IC50 = 3-6 µM) and other PKC isoforms only
at higher concentrations (IC50 for PKC and = 30-42 µM; IC50 for PKC , , and is 80-100 µM) (40). We found that rottlerin did not inhibit
AMø or PMø phagocytosis of apoptotic thymocytes at 10 µM (a concentration at which PKC should be inhibited
(40)), whereas there was significantly decreased phagocytosis at 40 µM (a concentration at which cPKCs should be inhibited
(40)) (Fig. 4). Ro-32-0432 had no effect
on phagocytosis of apoptotic thymocytes at 9 nM (a
concentration at which PKC should be inhibited (41)) but did
inhibit phagocytosis of apoptotic thymocyte at 28 nM (a
concentration at which PKC but not PKC should be inhibited
(41)) (Fig. 5). These data argue against
a requirement for PKC or PKC for phagocytosis of apoptotic
cells and provide additional support for the possibility that a cPKC,
especially PKC I or II, is required. However, rottlerin can
inhibit casein kinase II and cAMP-dependent protein kinase
with IC50 values of 30 and 78 µM, respectively, and can also inhibit calmodulin kinase III
with IC50 of 5.3 µM (32).
Moreover, interpretation of these experiments is complicated by the
uncertainty about the degree to which the reported IC50
values for these inhibitors can be extrapolated from the in
vitro assays with which they were developed to intact cells.
Therefore, we looked for an additional method to verify a requirement
of PKC during phagocytosis.
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Fig. 4.
Rottlerin inhibits Mø phagocytosis of
apoptotic thymocytes in a dose-dependent fashion.
Phagocytosis of apoptotic thymocytes by resident AMø and PMø was
determined after a 30-min incubation under the following conditions:
control medium (light gray bars), 10 µM rottlerin (black bars), 40 µM rottlerin (white bars), and 100 µM rottlerin (dark gray
bars). A, percentage of phagocytic Mø;
B, phagocytic index. Data are mean ± S.E. of three
replicates and are representative of results of two experiments. *,
p < 0.05, analysis of variance with post
hoc Dunnett's testing.
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Fig. 5.
Ro-32-0432 inhibits Mø phagocytosis of
apoptotic thymocytes in a dose-dependent fashion.
Phagocytosis of apoptotic thymocytes by resident AMø and PMø was
determined after 30 min of incubation under the following conditions:
control medium (gray bars), 9 µM
Ro-32-0432 (black bars), 28 µM
Ro-32-043 (white bars). A, percentage
of phagocytic Mø; B, phagocytic index. Data are
mean ± S.E. of four replicates in two experiments. *,
p < 0.05, analysis of variance with post
hoc Dunnett's testing.
II Blocking Peptide Inhibits Phagocytosis of
Apoptotic Thymocytes by AMø and PMø--
Because all data thus far
implicated a cPKC as a necessary signaling component during
phagocytosis of apoptotic thymocytes, we tested the effect of
cell-permeable myristoylated peptides derived from the carboxyl
terminus of the V5 region of PKC , I, or II, on phagocytosis
of apoptotic thymocytes. Peptides from this region were selected based
on the following rationale. First, this region (specifically the last
13 amino acids) has been suggested to contribute to
phosphatidylglycerol-induced activation of PKC II (29) and, via
interaction with the C2 region, to calcium-and PS-mediated activation
of PKC II (42). Second, the V5 region of PKC , specifically the
QSAV sequence, has been shown to interact with PICK1, a PKC-binding
protein that appears to target PKC to appropriate intracellular
sites for transduction of isozyme-specific signals (43). Third, the PKC
II peptide used in this study has previously been shown to inhibit
the binding of a maltose-binding protein-PKC II fusion protein to
RACK1 (34), confirming its functional activity. Fourth, the V5 region
is the only site at which PKC I and PKC II amino acid sequences
differ. Finally, these I and II peptides comprise part of the
antigenic sequences used for development of the isozyme-specific
antibodies used in this study.
II peptide significantly
decreased phagocytosis of apoptotic thymocytes by both AMø and PMø,
whereas the myristoylated PKC and PKC I peptides had no effect
(Fig. 6). These results provide direct
evidence that PKC II is required for Mø phagocytosis of
apoptotic thymocytes.
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Fig. 6.
Myristoylated PKC II
blocking peptide specifically inhibits Mø phagocytosis of apoptotic
thymocytes. Phagocytosis of apoptotic thymocytes by resident AMø
and PMø was determined after 30 min of incubation in control medium
(light gray bars) or in medium
containing a final concentration of 100 µM in water of
one of the following myristoylated blocking peptides: PKC peptide
(black bars), PKC I (white
bars), or PKC II peptide (dark gray
bars). A, percentage of phagocytic Mø;
B, phagocytic index. Data are mean ± S.E. of three
replicates and are representative of two experiments.
I, II,
, , µ, and to Membrane and Cytoskeleton
Fractions--
Translocation from cytosol to membrane or cytoskeleton
fractions upon activation is a major mechanism of PKC regulation (26, 44), leading us to investigate translocation of individual PKC isoforms during the phagocytic process. However, preliminary
experiments showed that the abundant expression of multiple PKC
isoforms in viable murine thymocytes was retained upon induction of
apoptosis,2 making use of apoptotic thymocytes for these
studies unfeasible. Instead, we substituted PS liposomes, which have
been used previously as models for apoptotic cells (45, 46). Liposome
clearance by AMø and PMø has been shown to require phagocytosis and
not to result from membrane fusion (47, 48), further supporting use of
PS liposomes for these studies. Based on the practical consideration
that our previous experiment showed that AMø express much lower
amounts of multiple PKC isoforms (Fig. 1), we performed these
experiments using only PMø. Time points were selected based on our
previous study of the kinetics of phagocytosis (10).
I, II, , , µ, and from the cytosol to the membrane and cytoskeleton fraction of PMø by 10 min, whereas control PI liposomes had no effect (Fig. 7). PS
liposomes specifically stimulated slight translocation of PKC , and
PI liposomes also slightly stimulated translocation of PKC and ,
whereas neither type of liposome had a significant effect on the
localization of PKC . Thus, several members of all three groups of
PKC isoforms are specifically translocated in response to PS
exposure.
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Fig. 7.
PS liposomes induce translocation of multiple
PKC isoforms into the membrane and cytoskeletal fractions.
Resident murine PMø were incubated for various times with liposomes
consisting of L- -PS (left-hand column) or
control L--PI (right-hand column), and then
expression of PKC isoforms in the cytosolic fraction and in the
membrane and cytoskeletal fraction was analyzed by Western blotting.
C, control (no liposomes).
View larger version (30K):
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Fig. 8.
Resident murine AMø and PMø
express PS-R'. A, reverse transcriptase-PCR analysis of
mRNA. Equally loaded PCRs were normalized to achieve the same
expression of the housekeeping gene glyceraldehyde-3-phosphate
dehydrogenase (right side) by adjusting the
volume of the cDNA product used in each reaction. The
black and white image was inverted
after scanning. Neg is a negative control, where no reverse
transcriptase reaction was performed and aliquots of RNAs from both
resident Mø were mixed. The reference ladder is 1 kb Plus
(Invitrogen). Results are representative of two experiments performed
with identical outcomes. B and C, flow cytometric
analysis of surface protein expression. AMø and PMø from normal
C57BL/6 mice were stained in suspension with mAb 217 culture
supernatant or with control IgM from a murine myeloma, with
biotinylated goat anti-mouse IgM F(ab'2), and with
streptavidin/phycoerythrin and then analyzed by flow cytometry,
counting 10,000 cells per condition. B, AMø; C,
PMø. The narrow line depicts staining with
isotype control, and the dark line depicts
staining with mAb 217. Representative histograms are shown; similar
results were obtained in four independent experiments.
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Fig. 9.
mAb against PS-R' blocks Mø phagocytosis but
not adhesion of apoptotic thymocytes. Resident AMø and PMø from
normal C57BL/6 mice were pretreated with saturating amounts of control
antibody (gray bars) or anti-PS-R' mAb 217 (black bars), and then phagocytosis or adhesion
of apoptotic thymocytes was determined by examining hematoxylin-eosin
Y-stained slides under oil immersion. A and B,
phagocytosis. Data are mean ± S.E. of 3-5 replicates per
condition in a single experiment. *, p < 0.05, unpaired t test. C and D, adhesion.
Data are mean ± S.E. of 3-5 replicates per condition in a single
experiment. Similar results were found in an additional
experiment.
II to particulate fractions. In the presence of control IgM,
PS liposomes induced translocation of PKC II from cytosolic
fractions to membrane and cytoskeletal fractions (Fig.
10, top row), as
anticipated from our previous results (Fig. 7). Such induced
translocation was inhibited when PS-R' was blocked using mAb 217 (Fig.
10, bottom row). These results indicate that the
induction of PKC II translocation by PS liposomes and, by implication, by apoptotic cells is mediated through PS-R'. Because mAb
217 itself has been shown to have agonist activity as indicated by its
ability to stimulate transforming growth factor- expression (12), in
separate experiments, we tested whether this mAb in the absence of PS
liposomes could induce PKC translocation. No induction of PKC
translocation was observed for PKC II or any of the other seven
isoforms tested.2 Thus, the effects shown in Fig. 10 result
from inhibition of PS-induced translocation mediated via PS-R' and not
from agonist activity of mAb 217 itself.
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Fig. 10.
Antibody against PS-R' inhibits PKC
II translocation induced by PS liposomes.
Resident PMø were incubated with saturating amounts of control rabbit
IgM (top row) or anti-PS-R' mAb 217 (bottom row) and exposed to PS liposomes to a
final concentration of 0.11 mM for up to 15 min at 37 °C
and 5% CO2, and then PKC II expression in cytosolic
versus membrane and cytoskeletal fractions was assayed by
Western analysis. C, control (no liposomes).
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
II is
required for phagocytosis of apoptotic cells by murine tissue Mø and
that the activation of this PKC isozyme in response to PS liposomes is
mediated by PS-R'. These conclusions are based on a consistent body of
evidence, including the effects on phagocytosis of PKC depletion by
overnight PMA treatment, dose-specific inhibition using rottlerin and
Ro-32-0432, and a specific myristoylated blocking peptide corresponding
to the carboxyl terminus of PKC II as well as by inhibition of
PS-induced translocation of PKC II when PS-R' was blocked. Because
adhesion of apoptotic thymocytes to Mø was not decreased by the PKC
inhibitor staurosporine (11) or by overnight PMA treatment, the
inhibition of phagocytosis seen in this study appears to result from
recognition events following binding. Our results also showed that
exposure to PS liposomes induced translocation of several other PKC
isoforms (I, , , µ, and , and to a lesser degree ) to
membrane and cytoskeletal fractions. However, based on results of the
inhibitor and PMA studies, translocation of these latter isoforms
appears to be unnecessary for phagocytosis. Furthermore, our results
indicated that the stereo-specific PS-R' did not mediate adhesion of
apoptotic cells, consistent with its predicted short extracellular
domain. Finally, Western blot analysis showed that murine AMø have
markedly lower expression of PKC II and of multiple other PKC
isoforms (, I, , , µ, and ), providing a
partial explanation for the previously demonstrated
relative deficit in apoptotic cell phagocytosis by that cell type (10).
These novel findings advance the understanding of signal transduction
during Mø recognition and ingestion of apoptotic cells.
II is necessary for Mø phagocytosis of
apoptotic cells is important because it differs from previously defined
requisites for Mø phagocytosis of other types of particles. Allen and
Aderem (49) found that during ingestion of zymosan by
lipopolysaccharide-stimulated PMø, PKC and myristoylated, alanine-rich protein kinase C substrate co-localized with F-actin and
talin adjacent to nascent phagocytic cups. During FcR-mediated phagocytosis, PKC (50), (51), (52), (53), and (50)
have all been shown to localize to the phagosome membrane, with the
specific PKC isoform recruited dependent on the state of Mø
differentiation and the exact FcR involved (52). However, because
PKC co-localization may be a consequence rather than a necessary
process, other groups have investigated blockade of PKC function.
Overexpression of a dominant negative mutant of PKC in the murine
Mø cell line RAW 264.7 reduced phagocytosis of IgG-opsonized sheep red
blood cells (54) but not phagocytosis of Leishmania donovani
promastigotes (55). Although the former finding was interpreted to
indicate a requirement for PKC in FcR-mediated phagocytosis,
such observations must be interpreted with caution, because
overexpression of one PKC isozyme can alter the levels of other PKC
isoforms (56). By contrast, using a combination of confocal microscopy,
various inhibitors, and biochemical evidence of PKC translocation in
RAW 264.7 cells, Larsen et al. (50) found that PKC was
needed for FcR-stimulated respiratory burst but that only PKC and were necessary for FcR-mediated phagocytosis itself. PKC
II and its anchoring protein RACK1 have been found to be
up-regulated in rat AMø upon maturation of functional responses such
as tumor necrosis factor- or hydrogen peroxide production and
lysozyme release (57). Significantly, however, none of these previous
studies have confirmed a role for PKC II in Mø phagocytosis of
other particles.
I and II are products of alternative mRNA splicing of a
single gene; they are identical for the first 621 amino acids and
differ only in their carboxyl-terminal 50-52 amino acids. The
myristoylated blocking peptides we used correspond to this area of
difference and therefore were specific. The absence of effect of
myristoylated I peptide on phagocytosis agrees with previous reports
that these isoforms have unique functions (28). Early studies found
that although both isoforms translocate to membranes in response to
short term PMA exposure, only PKC II is an actin-binding protein
that translocates to the actin-based cytoskeleton (58). However, recent
studies have reached conflicting conclusions, showing either that PKC
II does not co-distribute with actin-based cytoskeleton upon PMA
treatment (59) or that PKC I as well as other PKC isoforms bind to
and are activated by F-actin (60, 61).
R-mediated phagocytosis in rat AMø by
leukotrienes is PKC-dependent, indicating that AMø can
respond to PKC-stimulatory molecules (70).
II, in normal human or rat AMø compared with
monocytes or other Mø (37, 69). Interestingly, we have also found
that, like murine AMø, the murine Mø cell lines RAW 264.7 and IC21
have markedly reduced expression of PKC II (but not PKC or
I), which correlates with their greatly reduced phagocytosis (but not adhesion) of apoptotic thymocytes relative to PMø.2
Significantly, the fact that Monick et al. (37) found the
greatest difference in PKC isoform expression between human AMø and
blood monocytes to be a reduction in PKC II in AMø implies that our findings can be extrapolated to normal human AMø, which we have recently found also have relatively depressed phagocytosis of apoptotic
lymphocytes.2
II, an isoform not
shown previously to be required for phagocytosis of other types of
particles. This unique PKC isoform requirement may be an important clue
to the signaling pathways that mediate suppression of Mø production of
proinflammatory mediators on ingestion of apoptotic cells (64, 65).
Activation of PKC II by PS-R' provides a partial explanation for the
essential role of this receptor in apoptotic cell ingestion.
ACKNOWLEDGEMENTS
FOOTNOTES
ABBREVIATIONS
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ABSTRACT
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EXPERIMENTAL PROCEDURES
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DISCUSSION
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