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J. Biol. Chem., Vol. 276, Issue 32, 30342-30349, August 10, 2001
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From the
Received for publication, March 16, 2001, and in revised form, May 10, 2001
Activation of myosin II by myosin light chain
kinase (MLCK) produces the force for many cellular processes
including muscle contraction, mitosis, migration, and other cellular
shape changes. The results of this study show that inhibition or
potentiation of myosin II activation via over-expression of a dominant
negative or wild type MLCK can delay or accelerate tumor necrosis
factor- The inflammatory cytokine tumor necrosis factor- While many of the molecules involved in transducing TNF-mediated cell
death in vivo have been identified, there are still aspects
of TNF signaling that are not understood, particularly with respect to
the cellular mechanisms that regulate trafficking and translocation of
TNFR-1 and DISC components to form an active death signaling complex.
In unstimulated cells TNFR-1 is localized primarily to the trans-Golgi
network (17) and therefore must move to the plasma membrane to be
accessible to TNF. Because Golgi vesicles are known to be associated
with actin, myosin IIA, and myosin IIB, it is likely that myosin motor
activities are an important regulatory component of this translocation
step (18-20). A role for myosin II motor activities in TNF has been
suggested in a previous study where an inhibitor of myosin light chain
kinase (MLCK), the principal protein kinase responsible for activation of myosin II, delayed TNF-induced apoptotic DNA fragmentation (21). In
this report we describe our examination of the role of myosin II
motor activities in regulating the intracellular trafficking of TNFR-1
and its associated DISC proteins during TNF-induced apoptosis. The
results presented in this study highlight a new role for myosin II
motor activities at an early step of apoptotic signaling that regulates
translocation of TNFR-1 to or within the plasma membrane.
Reagents and Antibodies--
In all experiments, murine or human
TNF- Cell Lines and Cell Culture--
MDCK cell lines expressing
either wild type (WT) or kinase-dead (KD) MLCK under the control of a
tetracycline-repressible transactivator were constructed by
co-transfection of pTRE-MLCK plasmids and pTK-Hyg into MDCK cells
already expressing Tet-VP16 transactivator (22, 23). Stable
neomycin/hygromycin-resistant cell lines were selected and
characterized for tetracycline-regulated expression of MLCK. The
exogenously expressed rabbit 150-kDa WT MLCK and a mutant with an
in-frame deletion of Lys-725 have been characterized previously (24,
25). Both MLCK cDNAs have a C-terminal "flag" epitope
(DYKDDDDK). MDCK cell lines expressing MLCK were routinely maintained
in Dulbecco's modified Eagle's medium supplemented with 10% (v/v)
fetal calf serum, 2 mM glutamine, 100 units/ml penicillin,
and 100 µg/ml streptomycin containing 2 µg/ml Doxycycline to
suppress exogenous MLCK expression. Expression of MLCK in the MDCK cell
lines was induced by plating cells at low density in Dulbecco's
modified Eagle's medium/fetal calf serum containing either 0 ng/ml
Doxycycline (KD MLCK) or 0.2 ng/ml Doxycycline (WT MLCK) for 24 h.
These conditions allow for stable, approximately equal expression
levels of the MLCKs. Cells that do not express exogenous MLCK and
maximally repressed MDCK cells (2 µg/ml Doxycycline) served as
controls for all experiments. Over-expression of either MLCK did not
have a deleterious effect on growth, doubling time, or morphology.
Western blotting and immunofluorescence were used routinely to monitor
the expression of the exogenous WT or KD MLCK to ensure that both cell
lines were expressing each MLCK at equal levels. Cells were maintained
at subconfluent levels (~30-50% density) during analysis.
Cell Death Quantitation--
MDCK cells were seeded at 5 × 104 cells/well in 6-well tissue culture dishes. Viable,
attached cells were identified and counted using trypan blue
exclusion. ML-7 and ML-9 were added to the culture medium
30 min before TNF treatment at 10 or 20 µM, respectively, and were present during the incubation with TNF. An equal amount of
vehicle (Me2SO, <0.1% final concentration) was
added to control cells at the same time. Cell viability is expressed as
the percent of the surviving TNF-treated cells compared with the
surviving control cells not treated with TNF.
Western Blotting--
Cellular proteins were extracted with
Nonidet P-40 lysis buffer (1% Nonidet P-40, 300 mM NaCl,
0.5 mM EGTA, 50 mM MgCl2, 10% glycerol, and 20 mM MOPS, pH 7, plus protease inhibitors)
and analyzed by Western blotting as described previously (26).
DNA Fragmentation--
Flow cytometric analysis of cells was
performed on a Becton Dickinson (Mountain View, CA) FACStar plus.
Adherent cells were trypsinized, pooled with floating cells, fixed in
5% acetic acid, 95% ethanol at Myosin II RLC Phosphorylation--
Phosphorylation of RLCs in
attached and floating cells was determined as described (28). Briefly,
the cellular proteins were precipitated with 10% trichloroacetic acid,
and the pellets were washed with acetone and dissolved in 8 M urea, 20 mM Tris, 23 mM glycine,
and 10 mM dithiothreitol. Western blotting with an
anti-myosin II RLC antibody was used to identify unphosphorylated, monophosphorylated, and diphosphorylated forms of RLC after
fractionation through a 10% glycerol-polyacrylamide gel and transfer
to nitrocellulose. The relative abundance of each RLC band was
determined by scanning densitometry. The scan data were used to
calculate the myosin II RLC phosphorylation index using the formula:
mol phosphate/mol RLC = P1 + 2 (P2)/U + P1 + P2, where U = % unphosphorylated RLC, P1 = % monophosphorylated RLC, and P2 = % diphosphorylated RLC.
Caspase-8 Activity--
MDCK cells (1 × 106
cells/100-mm dish) were washed with PBS and lysed with CHAPS lysis
buffer (1% CHAPS, 100 mM NaCl, 100 µM EDTA,
10 mM dithiothreitol, and 50 mM HEPES, pH 7.4).
After centrifugation, cell extracts were incubated at 25 °C in assay
buffer (CHAPS lysis buffer plus 10% glycerol) with 200 µM Ac-IETD-pNA (Calbiochem), a colorimetric caspase-8
specific peptide substrate. The time-dependent change in
absorbance at 405 nm was monitored by spectrophotometry and converted
to caspase-8 activity (pmol/min/mg of total protein). Pure
p-nitroaniline (pNA, Calbiochem) was used for a
standard curve, and the caspase-8-specific inhibitor Ac-IETD-CHO
(Calbiochem) was added to each cell lysate as negative control.
Fractionation and Biotin Labeling of Membrane
Proteins--
Cells were washed four times with PBS and incubated in
0.5 mg/ml biotin-X-NHS (Calbiochem) in PBS containing 1 mM
MgCl2 and 0.1 µM CaCl2
(PBS/CM) for 30 min at 4 °C. After washing 5 times with PBS/CM,
cells were lysed in SDS lysis buffer (1% SDS, 150 mM NaCl,
50 mM Tris-HCl, pH 7.4). Soluble proteins were collected after centrifugation at 16,000 × g for 10 min and then
incubated for 1 h at room temperature with 0.2 g of
avidin-agarose beads (Calbiochem). The avidin-agarose beads were
pretreated by incubation with 20 mg/ml BSA in SDS lysis buffer. The
beads were washed five times in SDS lysis buffer to remove unbound,
non-biotinylated proteins and boiled in 2× protein gel sample buffer
for 5 min to solubilize biotinylated, bound membrane proteins prior to
analysis by SDS-polyacrylamide gel electrophoresis and Western
blotting. Conditions for biotin labeling and subsequent fractionation
of labeled cell surface proteins by avidin-agarose chromatography were
optimized using Western blotting to confirm that cytoplasmic or nuclear
proteins were absent in the biotin-labeled fraction.
Immunofluorescence Labeling and Microscopy--
Cells were fixed
and processed for immunofluorescence in the presence of 3.7%
paraformaldehyde and 0.1% Triton X-100. Photomicrographs were adjusted
using Photoshop; each image was treated identically.
Inhibition of Myosin II RLC Phosphorylation Delays the Progression
of TNF-induced Apoptosis in MDCK Cells--
To determine whether
myosin II motor activities have a role in TNF-induced cell death,
myosin II RLC phosphorylation and thus myosin II activation was
inhibited through the use of two MLCK-specific inhibitors, ML-7
(Ki = 0.3 µM) and ML-9
(Ki = 3.8 µM). The effects of MLCK
inhibitors on TNF-mediated cell death were examined in MDCK cells,
which are sensitive to the apoptotic effects of TNF in the absence of
cycloheximide. Treatment of MDCK cells with ML-7 (Fig.
1A) or ML-9 (data not shown)
slows the rate of MDCK cell death, and the t1/2 for
cell death (time at which 50% cell death occurs) is extended from
44 h to 60 h in the presence of ML-7. Paralleling the delay in cell death were delays in the appearance of fragmented DNA and the
89-kDa PARP cleavage product (not shown). Use of these MLCK
inhibitors also resulted in a decrease in the peak of TNF-induced RLC
phosphorylation at 30 min from 0.94 ± 0.05 mol Pi/mol
RLC to 0.51 ± 0.02 mol Pi/mol RLC, suggesting that
inhibiting myosin II RLC phosphorylation delays TNF-induced apoptotic
cell death (Fig. 1B).
To further determine the role of myosin II motor activities in
TNF-induced cell death, MDCK cell lines over-expressing an inactive, KD
or WT Ca2+/calmodulin-dependent MLCK under the
control of the tetracycline promoter were generated. Based upon
previous studies, KD MLCK was expected to act as a dominant negative to
compete with the endogenous MLCK and reduce RLC phosphorylation and
myosin II activation (25). Characterization of these cell lines
revealed that continuous over-expression of either maximal or moderate
levels of these MLCKs does not result in alterations in survival or
growth rates in the absence of TNF. However, in the presence of 10 ng/ml TNF, the temporal progression of cell death for MDCK cells
expressing KD MLCK was significantly delayed compared with that of the
parental cell line or MDCK cells over-expressing WT MLCK (Fig.
2A). The levels of RLC
phosphorylation were quantitated following 15 or 30 min of TNF
treatment when RLC phosphorylation was observed to peak in the parental
MDCK cells (Fig. 1). These results showed that the levels of RLC
phosphorylation in MDCK cells expressing KD MLCK are significantly
lower at both time points (0.71 ± 0.06 and 0.80 ± 0.4 mol
Pi/mol RLC, respectively) compared with the parental MDCK
cells (0.86 ± 0.06 and 0.95 ± 0.03 mol Pi/mol
RLC, respectively) (Fig. 2B). In contrast, the levels of RLC
phosphorylation in the MDCK cells expressing WT MLCK were elevated to
1.4 ± 0.1 at 15 min or 1.2 ± 0.1 at 30 min (Fig.
2B).
DNA fragmentation, PARP cleavage, and the rate of cell death were also
compared in parental MDCK cells and MDCK cells over-expressing KD or WT
MLCK. Degradation of high molecular weight chromosomal DNA into smaller
fragments was examined using flow cytometry (Fig. 2C).
Comparison of the DNA fragmentation occurring in the parental MDCK
cells and MDCK cells expressing KD or WT MLCK showed that following
30 h of TNF treatment, over-expression of the dominant negative KD
MLCK decreases TNF-induced DNA fragmentation (<5% of cells). In
contrast, more than 30-40% of the MDCK cells expressing WT MLCK were
found in the hypodiploid, sub-G1 peak (Fig. 2C)
as compared with 15-20% of the parental MDCK cells.
To determine when myosin II motor activity is important in the
TNF-induced apoptotic pathway, the activation of distal execution caspases such as caspase-3 was examined by monitoring the appearance of
an 89-kDa cleavage fragment of PARP (29, 30). The 89-kDa PARP fragment
is first detectable by Western blotting in the parental MDCK cells
after 24 h of TNF treatment (Fig. 2D). However, the appearance of the PARP cleavage product is delayed until 48 h in
MDCK cells expressing the dominant negative KD MLCK. In contrast, in
MDCK cells expressing WT MLCK, the 89-kDa PARP cleavage fragment is
rapidly detectable within 8 h of TNF treatment. This result demonstrates that activation of receptor distal proteases such as
caspase-3 is delayed by decreasing MLCK activity and places the role of
Ca2+/calmodulin-dependent MLCK activity and RLC
phosphorylation at a point upstream of activation of caspase-3 in the
TNF-induced apoptotic signaling cascade.
The Rates of Intracellular Movement of TNFR-1-associated DISC
Proteins Are Regulated by Changes in Myosin II Motor Activity--
An
examination of the intracellular distribution of both FADD and
caspase-8 in permeabilized MDCK cells in response to TNF demonstrated
that within 15 min of TNF stimulation, a dramatic alteration in the
appearance of death signaling proteins occurred (Fig.
3). In unstimulated MDCK cells, FADD had
an indistinct cytosolic pattern and reorganized within 15 min to form
visible complexes resembling small filamentous perinuclear aggregates
in MDCK cells over-expressing WT MLCK. In comparison, in MDCK cells
over-expressing KD MDCK, aggregates did not become visible until
after at least 3 h of TNF treatment. Procaspase-8 was also
found to reorganize into visible aggregates in MDCK cells
over-expressing WT MLCK within 15 min of TNF treatment but was
delayed until ~3 h in MDCK cells expressing the dominant negative KD
MLCK (Fig. 3). The decrease in the pro-caspase-8-reactive protein
observed at 3 h for MDCK cells over-expressing WT MLCK is
consistent with the fact that the antibody used to detect procaspase-8
in fixed cells does not react with the cleaved form of active caspase-8
(31). These results show that within 15 min of TNF treatment, a
dramatic change in the intracellular distribution of FADD and
pro-caspase-8 occurs; this reorganization is dependent on the relative
levels of MLCK activity. Together these results demonstrated that the
rate of aggregation and activation of the apical death signaling
caspase, procaspase-8, can be modulated by changes in MLCK
activity.
Consistent with the proposal that FADD and caspase-8 aggregation is
dependent on myosin motor activity, we determined that the percent of
increase in TNF-induced activation of caspase-8 was abrogated
significantly at all time points between 1 and 8 h in MDCK cells
expressing the dominant negative KD MLCK. However, by 24 h the
increase in caspase-8 activity approached that of the parental MDCK
cells. In contrast, within 8 h of TNF treatment, the caspase-8
activity in WT MDCK cells rapidly increased to surpass the maximal
activity level determined for the parental MDCK cells (Fig.
4). Following this accelerated peak, the
caspase-8 activity levels declined as the population of WT MDCK cells
was decimated by apoptosis. For these experiments, a colorimetric assay
that results from cleavage of a caspase-8-specific substrate,
Ac-IETD-pNA, was used to directly determine caspase-8 activity in cell
extracts. Together, the physical aggregation and changes in activity of capase-8 reflected the relative levels of MLCK activity in these TNF-treated MDCK cells and were consistent with the suggestion that
myosin motor activities may have a role in the intracellular distribution of components of the TNFR-1 signaling cascade. However, these experiments did not address the possibility that the
intracellular aggregates are associated with TNFR-1 at the cell
surface membrane.
Intracellular Trafficking of TNFR-1 Is Regulated by Myosin II Motor
Activity--
To determine whether myosin II motor activity has a role
in movement and activation of death signaling by TNFR-1, proteins located on the plasma membrane were labeled by treating the intact cell
monolayer with biotin-X-NHS. Following biotin labeling at 4 °C, the
cells were lysed and the biotin-labeled proteins were purified using
avidin-agarose chromatography as described under "Materials and
Methods." Western blotting of the avidin-agarose fractions using an
anti-TNFR-1 antibody revealed that at the zero time point, in the
absence of TNF stimulation, only a small fraction of TNFR-1 is on the
plasma membrane (Fig. 5). In response to
TNF, the relative amount of TNFR-1 that becomes biotin-labeled rapidly increased in MDCK cells and MDCK cells over-expressing WT MLCK and was
readily detectable within 15 min. In contrast, TNFR-1 was not detected
on the plasma membrane of MDCK cells that over-express the dominant
negative, KD MDCK, until between 3 and 8 h.
LPS or Ionomycin Both Result in the TNF-independent Translocation
of TNFR-1 to the Plasma Membrane--
To determine whether
translocation of TNFR-1 requires TNF or whether activation of MLCK and
myosin II motor activities alone is sufficient for translocation, MDCK
cells were stimulated either with ionomycin or LPS (endotoxin), and the
levels of RLC phosphorylation and TNFR-1 in the biotin-labeled fraction
were determined. Ionomycin was expected to elevate intracellular
calcium, leading to activation of MLCK and myosin motor activities. In
support of a TNF-independent translocation mechanism, the parental MDCK
cells and the WT MLCK over-expressing cell line treated for 5 min in
the presence of 10 µM ionomycin had significantly
increased levels of RLC phosphorylation compared with
Me2SO-treated controls (Fig.
6A). In addition, the amount
of TNFR-1 in the biotin-labeled fraction of the parental and WT
MLCK-expressing MDCK cells was also increased (Fig. 6B). MDCK cells over-expressing KD MLCK had no significant increase in RLC
phosphorylation and little detectable TNFR-1 on the plasma membrane in
response to ionomycin. Finally, the MLCK inhibitor, ML-7, abrogated the
ionomycin-stimulated increase in TNFR-1 on the plasma membrane in the
parental and MDCK cells over-expressing WT MLCK to levels similar to
that found in the unstimulated control cells (Fig. 6B).
LPS, or endotoxin, is a component of the cell walls of Gram-negative
bacteria that stimulates macrophages and other cells to release
pro-inflammatory cytokines including TNF. In addition to stimulating
cytokine expression, bacterial sepsis also induces contractile
responses and loss of barrier function in cells like endothelial cells
through activation of myosin II motor activities (32). This LPS-induced
activation of myosin motor activities could provide a mechanism for
translocation of vesicles containing TNFR-1 to the plasma membrane
where TNF binding can initiate signaling. To determine whether LPS
stimulates TNFR-1 translocation to the plasma membrane, experiments
were conducted to evaluate the level of apoptosis in cells that were
not pretreated LPS (TNF only) or were treated simultaneously with TNF
and LPS. The results of these experiments showed that the presence of
LPS does not alter the extent of apoptosis in KD or WT MLCK-expressing
cells or in the parental MDCK cells. However, pretreatment of MDCK
cells for 8 h with LPS (1 µg/ml) enhanced the extent of
apoptosis in the MDCK cell lines expressing KD MLCK and the
parental MDCK cells from ~48 and 62% to 80 and 93%, respectively.
Similar results were obtained whether or not LPS was maintained in the
presence of TNF. LPS pretreatment had little or no effect on the extent of apoptosis in MDCK cells expressing WT MLCK, most likely because these cells already exhibit maximal levels of apoptosis by 48 h in
the absence of LPS. Control experiments utilizing MDCK cell lines
treated for 56 h with LPS showed only that LPS does not induce
apoptosis by itself (data not shown). To further establish that LPS can
stimulate myosin motor activities and subsequent translocation of
TNFR-1 to the plasma membrane, the levels of RLC phosphorylation and
surface TNFR-1 in response to LPS treatment were determined (Fig.
7B). RLC phosphorylation in
MDCK cells expressing KD MLCK gradually increased from 0.5 ± 0.05 mol Pi/mol RLC to a peak level of ~1.1 ± 0.17 mol
Pi/mol RLC in response to LPS, and this level appeared to
be maintained between 3 and 8 h. In contrast, RLC phosphorylation
in MDCK cells expressing WT MLCK rapidly increased from 0.5 ± 0.1 to 1.7 ± 0.1 mol Pi/mol RLC after 15 min of LPS and
then slowly declined to ~1.15 ± 0.1 mol PI/mol RLC by 8 h.
The surface levels of TNFR-1 also corresponded to the changes in RLC
phosphorylation and gradually increased in KD MDCK to approximate the
surface level of TNFR-1 detected in WT-expressing MDCK cells. Together
these results suggested that myosin motor activities are important for
translocation of TNFR-1 to the plasma membrane.
Although a detailed characterization of the signaling pathways
emanating from TNFR-1 has been compiled, little is known about signaling mechanisms that regulate the intracellular or intramembrane trafficking of this death receptor. The pivotal importance of myosin II
motor activities in other contractile processes like mitosis,
migration, and cellular shape changes, including muscle contraction,
are well established. In this study we show that myosin II motor
activity also has an important role in regulating the apoptotic
signaling cascade activated by TNF and is directly involved in
translocation of TNFR-1 to a biotin-accessible location on the cell
membrane. The experiments in this report utilized both direct and
indirect modulation of myosin II motor activities by pharmacological
agents, or the expression of a dominant negative or WT MLCK, to link
changes in RLC phosphorylation to changes in the rate of TNF-induced
apoptotic cell death in MDCK cells. These results show that
translocation of TNFR-1 to a biotin-accessible membrane location is a
myosin II-dependent motor process that can occur in the
absence of TNF in response to either increased intracellular calcium or
to LPS, a physiological activator of cytokine signaling.
Myosin II Motor Activities Regulate TNF-induced
Apoptosis--
MLCK is the primary regulator of myosin II ATPase
activity, and in contrast to most other Ser/Thr protein kinases, MLCK
has a single, well characterized physiological substrate, the myosin II
RLC. Phosphorylation of myosin RLC by MLCK leads directly to activation
of myosin II ATPase and myosin II force production. Based upon this
pathway we hypothesized that if myosin II motor activities have a role
in regulating TNF signaling, then changes in the total MLCK activity in
cells will directly impact the progression of apoptosis. Consistent
with this proposal, our results demonstrate that increasing or
decreasing the total MLCK activity in cells, either by over-expression
of WT MLCK or dominant negative KD MLCK or by the use of a specific
inhibitor of MLCK, ML-7, leads to a corresponding change in RLC
phosphorylation and to either potentiation or abrogation of TNF-induced apoptosis.
By examining the signaling pathway that is initiated by TNF, we show
that the downstream activities of the caspases that are activated by
TNF signaling respond in parallel to changes in myosin motor activity.
In addition, we have noted a rapid reorganization of both FADD and
caspase-8 into small aggregates in response to TNF. Although it is
unclear whether the aggregates are associated with TNFR-1, the data
suggest that the formation of FADD and caspase-8 aggregates is linked
to myosin II motor activities, as evidenced by the difference in the
rates of TNF-induced aggregation observed in MDCK cells expressing WT
and KD MLCK. The rapid aggregation and coordinated increase in
caspase-8 activity are consistent with the recently proposed model of
proximity-induced auto-activation (13, 33). However, in contrast to
other studies we do not see the formation of large cytoplasmic
filamentous aggregates, called death effector filaments, that have been
described for FADD and caspase-8 (34-36). This distinction could be
because we are examining changes in intracellular distribution by
endogenous FADD and caspase-8, which may only form smaller aggregates,
and suggests that the larger, filamentous death effector filaments are
a consequence of over-expression.
Finally, we also show that the translocation of TNFR-1 from a
biotin-inaccessible to a biotin-accessible plasma membrane location is
linked to myosin motor activities. This observation is consistent with
previous studies showing that the bulk of TNFR-1 is localized to the
trans-Golgi (17) and suggests that myosin II forces can power the
translocation of a Golgi-derived vesicle containing TNFR-1 to the
plasma membrane (18, 37). Consistent with this suggestion are several
recent reports showing that nonmuscle myosin IIA and possibly IIB as
well as F-actin are associated with distinct Golgi vesicles. The
association of actomyosin filaments with Golgi-derived vesicles that
contain TNFR-1 could provide the necessary forces for the intracellular
trafficking of these vesicles (18, 19, 37, 47, 48). Alternatively, or
additionally, these results suggest that myosin II motor activities may
translocate TNFR-1 within the plasma membrane from a
biotin-inaccessible to a biotin-accessible location.
Is TNF Required for Translocation of TNFR-1 to the Plasma
Membrane?--
These results raised the issue of whether stimulation
of cells with TNF is required for receptor translocation or whether actomyosin motor activities alone can promote translocation of TNFR-1
to the cell membrane. Experiments using either LPS or ionomycin both
showed that activation of myosin II motor activities is sufficient to
result in translocation of TNFR-1 to the plasma membrane in the absence
of TNF. Treatment of MDCK cells with ionomycin, a calcium ionophore,
increases RLC phosphorylation, and this is paralleled by a rapid
increase in the level of biotinylated TNFR-1 detected on the plasma
membrane. Similarly, treatment of MDCK cells with LPS, an inflammatory
response mediator, also results in increased RLC phosphorylation and a
parallel increase in surface expression of TNFR-1. Rapid and sustained
increases in intracellular calcium have been demonstrated in septic
shock induced by endotoxin (LPS) (38-41). In addition, LPS-induced
septic shock is known to cause a rapid, contractile response in
endothelial cells through increased RLC phosphorylation (32).
Therefore, it is reasonable to expect that increases in intracellular
calcium occur in response to LPS. This would lead to activation of
MLCK, to result in increased RLC phosphorylation, stimulation of myosin
II motor activity, and translocation of TNFR-1 to the plasma membrane
where ligand binding would activate TNFR-1 signaling. We also
considered the possibility that the response to LPS for these MDCK
cells occurs via LPS-induced synthesis of TNF. This does not appear to
be a likely possibility, as increases in RLC phosphorylation and
translocation of TNFR-1 to the plasma membrane are detected within 15 min of LPS addition to the cultures, making it unlikely that de
novo expression and autocrine stimulation by TNF is involved in
translocation of TNFR-1. Finally, we show that pretreatment of the
cells with LPS can increase the extent of apoptosis as well as lead to
a sustained accumulation of TNFR-1 on the plasma membrane. Together these findings are consistent with the suggestion that LPS can activate
myosin II motor activities to result in the translocation of TNFR-1. In
addition, these results suggest that LPS activation of myosin motor
activities may serve to prime cells for TNF-induced signaling.
Is TNFR-1 Translocation Dependent on MLCK Activity?--
Several
experiments in this report show that the surface level of TNFR-1 is
decreased in TNF-stimulated MDCK cells expressing KD MLCK. In addition,
MDCK cells treated with ionomycin in the presence of the MLCK,
inhibitor ML-7 also have decreased surface levels of TNFR-1. Together
these experiments suggest that the Ca2+/calmodulin-dependent MLCK may be involved
directly in the activation of myosin II motor activity for
TNFR-1 translocation. However, even the over-expression of a dominant
negative KD MLCK is insufficient to completely block the apoptotic
effects of TNF. One reason for this finding may be that the exogenously
expressed 150-kDa KD MLCK is unable to compete completely with the
endogenous 220-kDa MLCK expressed in MDCK cells because these two forms
of MLCK have distinct intracellular
locations.2 Alternatively,
other protein kinases known to phosphorylate myosin II RLC, such as
Rho-dependent kinase, p21-activated kinase, or the
Ca2+/calmodulin-dependent death-associated
protein kinase may act either independently of or in addition to MLCK
(42-46) to activate myosin II motor activities for translocation of
TNFR-1 to the plasma membrane. Additional studies will be required to
define the relative contributions of the two MLCK forms as well as
other RLC protein kinases to receptor trafficking in cells.
The growing list of myosin II motor activities that includes
contractile processes such as migration, cytokinesis, and muscle contraction illustrates the pivotal importance of myosin functions. In
this report we show that myosin II motor activities are important at an
early step in TNF signaling and power the translocation of TNFR-1 to or
within the plasma membrane. We also show that activation of myosin II
motor activities independently of TNF stimulation is sufficient for
translocation of TNFR-1 to a biotin-accessible membrane location and
can occur as a result of increasing intracellular calcium. Together
these results suggest a model by which TNF receptor movements may be
regulated (Fig. 8). In this model the
relationship between calcium, MLCK, myosin II activity, and the
intracellular distribution of TNFR-1 are emphasized. Stimulation of
cells with TNF, ionomycin, or LPS is postulated to cause an increase in
intracellular calcium and result in the activation of myosin II motor
activity through RLC phosphorylation by the
Ca2+/calmodulin-dependent MLCK. The activation
of myosin motor activities provides the force for translocating TNFR-1
containing vesicles from the Golgi to the plasma membrane where they
fuse to expose the receptor for ligand binding. Alternatively, or in
addition, myosin II motor activities may drive the redistribution of
TNFR-1 within the plasma membrane. Following movement to or within the plasma membrane, the binding of TNF then induces trimerization of
TNFR-1 followed by the recruitment of TRADD, FADD, and caspase-8, to
result in activation of the cell death pathway. Activation of TNFR-1
may also lead to a sustained increase in intracellular Ca2+
to provide additional myosin-driven translocation of the receptor. Overall these studies show that myosin II motor activities are important for the translocation and regulation of the surface level of
TNFR-1 and ultimately for the response of the cell to TNF.
We thank Bradley A. Poteat for his technical
assistance in preparation of the cell lines.
*
This work was supported by National Institutes of Health
Grant HL54118 (to P. J. G.).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.
§
Recipient of an American Heart Association-Midwest Affiliate
pre-doctoral fellowship.
Published, JBC Papers in Press, May 30, 2001, DOI 10.1074/jbc.M102404200
2
P. J. Gallagher, unpublished observation.
The abbreviations used are:
TNF, tumor necrosis
factor-
Myosin II Light Chain Phosphorylation Regulates
Membrane Localization and Apoptotic Signaling of Tumor Necrosis
Factor Receptor-1*
§,
Department of Cellular and
Integrative Physiology and the ¶ Department of Medicine, Indiana
University School of Medicine, Indianapolis, Indiana 46202
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
(TNF)-induced apoptotic cell death in cells. Changes in the
activation of caspase-8 that parallel changes in regulatory light
chain phosphorylation levels reveal that myosin II motor
activities regulate TNF receptor-1 (TNFR-1) signaling at an early step
in the TNF death signaling pathway. Treatment of cells with either
ionomycin or endotoxin (lipopolysaccharide) leads to activation of
myosin II and increased translocation of TNFR-1 to the plasma membrane
independent of TNF signaling. The results of these studies establish a
new role for myosin II motor activity in regulating TNFR-1-mediated
apoptosis through the translocation of TNFR-1 to or within the plasma membrane.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
(TNF)1 has an important role
in many diverse cellular events, including cell proliferation and
apoptosis (1-4). TNF signals through two receptors, TNFR-1 and TNFR-2,
which are members of the TNF receptor superfamily. Of the two receptors
for TNF, TNFR-1 is associated principally with signaling that results
in either apoptosis or activation of the transcription factor
NF-
B (5). Binding of TNF to TNFR-1 initiates death signaling
by inducing trimerization of TNFR-1, aggregation of the cytoplasmic
death domains, and recruitment of TNF receptor-associated death domain
protein (TRADD) to the cytoplasmic death domain of TNFR-1 (3, 6-9).
Subsequently, Fas-associated death domain protein (FADD/MORT1) is
recruited to form a death-inducing signaling complex (DISC), which
initiates apoptosis through recruitment and activation of procaspase-8
(FLICE/MACH/Mch5) (3, 10-12). Auto-activation of the initiator
caspase, caspase-8, occurs upon oligomerization following its
recruitment to FADD (13) and is a key step in the execution of the
death receptor pathway for apoptosis. Caspase-8 then activates
downstream effector caspases, which cleave the structural and
regulatory proteins necessary for cell survival (14-16).
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
(Calbiochem, La Jolla, CA) was used at 10 ng/ml and gave the
same results. Ionomycin and lipopolysaccharide ((LPS) endotoxin) were
from Calbiochem. Polyclonal antibodies to TRADD and poly(A)DP-ribose
polymerase (PARP) were obtained from Santa Cruz Biotechnology (Santa
Cruz, CA). Anti-procaspase-8 and FADD were from Calbiochem. Polyclonal antibody to TNFR-1 was from Stressgen (Victoria, British Columbia, Canada). A polyclonal antibody to purified myosin II regulatory light
chains (RLC), was generated and characterized in this laboratory.
20 °C, and stained with 50 µg/ml propidium iodide (Sigma) (27). At least 10,000 cells
were counted for each analysis.
RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
An inhibitor of MLCK activity delays
TNF-induced apoptosis and decreases RLC phosphorylation in MDCK
cells. MDCK cells were treated with TNF (10 ng/ml) for indicated
times in the presence of ML-7 (10 µM) or vehicle (0.1%
dimethyl sulfoxide (DMSO)). Apoptosis (A) and RLC
phosphorylation (B) were determined at the indicated time
points. The percent apoptosis (%) was determined by counting the
number of viable attached cells after the indicated times of TNF
treatment and comparing them with the number of viable cells in
untreated controls. The relative levels of total phosphate
incorporation into myosin II RLC were determined following
urea-glycerol gel electrophoresis and Western blotting using a specific
anti-RLC antibody. The extent of myosin II RLC phosphorylation was
calculated as moles of phosphate incorporated per mole of RLC
(mol Pi/mol RLC). The results show that
ML-7 delays TNF-induced apoptosis and decreases RLC phosphorylation in
MDCK cells. The results represent the mean ± S.E. of at least six
independent experiments.
View larger version (35K):
[in a new window]
Fig. 2.
A dominant negative, kinase-dead MLCK
abrogates TNF-induced apoptosis in MDCK cells. A, time
course of TNF-induced apoptosis in the parental (MDCK) and
MDCK cells expressing KD MLCK (KD) or WT MLCK
(WT). Equivalent numbers (5 × 104) of
cells were seeded, and the percent apoptosis was determined at the
indicated times of treatment with TNF (10 ng/ml). B, myosin
II RLC phosphorylation levels in parental (MDCK) and in MDCK
cell lines expressing inactive, kinase-dead (KD), or
wild-type MLCK (WT). The levels of total phosphate
incorporation into myosin II RLC were determined at 0, 15, and 30 min
of TNF treatment using urea-glycerol gel electrophoresis and Western
blotting with a specific anti-RLC antibody. The extent of myosin II RLC
phosphorylation was calculated as moles of phosphate incorporated per
mole of RLC (mol Pi/mol RLC). The results
shown in panels A and B represent the mean ± S.E. from six experiments. C, flow cytometric analysis of
TNF-treated MDCK cells and MDCK cell lines expressing WT or KD MLCK.
Following 30 h of TNF treatment, cells were dissociated, fixed,
and treated with propidium iodide (PI). The DNA content of
10,000 cells was analyzed by flow cytometry as described under
"Materials and Methods." Results shown are representative of three
independent experiments. The approximate locations of the peaks
representing diploid DNA content (G1), tetraploid
(G2), or hypodiploid (<G1; arrow) are
indicated. D, parental MDCK or MDCK cells expressing KD MLCK
or WT MLCK were treated with TNF (10 ng/ml) for the indicated times,
and full-length (116 kDa) and caspase-cleaved (89 kDa) PARP were
detected by Western blotting. Each lane represents 50 µg
of total protein.
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[in a new window]
Fig. 3.
TNF treatment causes FADD and caspase-8 to
form aggregates. Indirect immunofluorescence with an anti-FADD or
anti-pro-caspase-8 antibodies was used to detect formation of FADD or
pro-caspase-8 aggregates in MDCK cells in response to TNF treatment (10 ng/ml). The pro-caspase-8 antibody is specific only for the pro-form
and does not react with mature caspase-8.
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[in a new window]
Fig. 4.
Caspase-8 activity is rapidly activated in
MDCK cells expressing WT MLCK. MDCK cells were treated with TNF
(10 ng/ml) for the indicated times, and caspase-8 activity was measured
as a change in absorbance at 405 nm using a colorimetric caspase-8
substrate, IETD-pNA.
View larger version (20K):
[in a new window]
Fig. 5.
Changes in MLCK activity alter translocation
of TNFR-1. TNFR-1 present on the plasma membrane in MDCK cells
expressing WT or KD MLCK were labeled at the indicated times by
treating intact cells with biotin. The biotin-labeled proteins were
isolated by avidin-agarose fractionation, and the TNFR-1 present in the
biotin-labeled membrane fraction (Surface) was detected by
Western blotting using a TNFR-1 antibody.
View larger version (34K):
[in a new window]
Fig. 6.
Ionomycin stimulates TNFR-1 translocation to
the plasma membrane. MDCK cell lines over-expressing either WT or
KD MLCK or parental (MDCK) cells were treated for 5 min with
ionomycin or with vehicle (dimethyl sulfoxide (DMSO)).
A, the levels of phosphate incorporation into myosin II RLC
(mol Pi/mol RLC) were determined
following urea-glycerol gel electrophoresis and densitometry of Western
blots using anti-RLC antibody to detect RLC. B, the relative
amounts of TNFR-1 in the biotin-labeled fraction were determined by
Western blotting using anti-TNFR-1 antibody. The amount of TNFR-1 in
the biotin-labeled fraction was also examined in the presence or
absence of the MLCK inhibitor ML-7. The results shown represent the
mean ± S.E. from four experiments.
View larger version (35K):
[in a new window]
Fig. 7.
LPS stimulates TNFR-1 translocation to the
plasma membrane. A, MDCK cell lines over-expressing
either WT or KD MLCK or parental (MDCK) cells were treated
with TNF (10 µg/ml) in the absence or presence of LPS (1 µg/ml) for
the indicated times, and the relative amounts of biotin-labeled TNFR-1
were determined as described in the legend for Fig. 6. B,
MDCK cell lines were treated with LPS (1 µg/ml) for up to
8 h. At the indicated times, the levels of phosphate incorporation
into myosin II RLC (mol Pi/mol RLC) and
surface expression of TNFR-1were determined. The results shown
represent the mean ± S.E. from four experiments.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
View larger version (27K):
[in a new window]
Fig. 8.
Pathway for myosin II regulation of TNFR-1
translocation to the plasma membrane. The stimulation of cells to
increase intracellular Ca2+ leads to activation of MLCK and
phosphorylation of myosin II RLC. RLC phosphorylation increases
actin-associated myosin II ATPase activity and provides the motor
activity to translocate a TNFR-1-associated vesicle from the Golgi to
the plasma membrane or within the plasma membrane, where TNF binds and
receptor trimerization occurs. Activated TNFR-1 recruits TRADD, FADD,
and pro-caspase-8. Continued TNF stimulation may amplify or prolong
increased intracellular Ca2+ signaling by activating
membrane calcium channels.
ACKNOWLEDGEMENT
FOOTNOTES
To whom correspondence should be addressed: Dept. of Cellular
and Integrative Physiology, 635 Barnhill Dr., Indianapolis, IN
46202-5120. Tel.: 317-278-2146; Fax: 317-274-3318; E-mail: pgallag@iupui.edu.
ABBREVIATIONS
;
TNFR-1, tumor necrosis factor receptor-1;
RLC, myosin II
20-kDa regulatory light chain;
TRADD, TNF receptor-associated death
domain protein;
MLCK, myosin light chain kinase;
FADD, Fas-associated
death domain protein;
LPS, lipopolysaccharide (endotoxin);
DISC, death-inducing signaling complex;
PARP, poly(A)DP-ribose polymerase;
MDCK, Madin-Darby canine kidney cells;
WT, wild type;
KD, kinase dead;
PBS, phosphate-buffered saline;
pNA, p-nitroaniline;
CHAPS, 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid;
MOPS, 4-morpholinepropanesulfonic acid.
REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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