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Previous Article | Next Article 
Molecular and Cellular Biology, November 2001, p. 7183-7190, Vol. 21, No. 21
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.21.7183-7190.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
MEKK1 Is Essential for DT40 Cell Apoptosis in
Response to Microtubule Disruption
Raymond
Kwan,1
Joan
Burnside,2
Tomohiro
Kurosaki,3 and
Genhong
Cheng1,4,*
Molecular Biology Institute1 and
Department of Microbiology, Immunology and Molecular Genetics,
Jonsson Comprehensive Cancer Center,4 University
of California Los Angeles, Los Angeles, California 90095-1781;
Department of Animal and Food Sciences, College of
Agriculture and Natural Resources, University of Delaware, Newark,
Delaware 19717-13032; and Department of
Molecular Genetics, Institute for Liver Research, Kansai Medical
University, Moriguchi 570-8506, Japan3
Received 27 March 2001/Returned for modification 23 May
2001/Accepted 10 August 2001
 |
ABSTRACT |
Vinblastine and other microtubule-damaging agents, such as
nocodazole and paclitaxel, cause cell cycle arrest at
the G2/M transition and promote apoptosis in
eukaryotic cells. The roles of these drugs in disrupting
microtubule dynamics and causing cell cycle arrest are well
characterized. However, the mechanisms by which these agents promote
apoptosis are poorly understood. We disrupted the MEKK1 kinase
domain in chicken bursal B-cell line DT40 by homologous recombination
and have shown that it is essential for both
vinblastine-mediated apoptosis and
vinblastine-mediated c-Jun N-terminal protein kinase activation. In
addition, our data indicate that vinblastine-mediated
apoptosis in DT40 cells requires new protein synthesis but does
not require G2/M arrest, suggesting that
vinblastine-mediated cell cycle arrest and apoptosis are two
independent processes.
| |
INTRODUCTION |
Eukaryotic cells treated with
microtubule-disrupting agents such as vinblastine, nocodazole, and
paclitaxel undergo cell cycle arrest at the G2/M transition
(19, 25). Because of their inhibitory effect on
proliferation, these drugs are used in the treatment of many types of
cancer. Cell cycle arrest at the G2/M transition after
treatment with these drugs is initiated by the G2/M
checkpoint in response to the disruption of the mitotic spindle
apparatus (4, 13), which is in part composed of
microtubules. At high concentrations, vinblastine and nocodazole
disrupt the mitotic spindle apparatus by binding to tubulin monomers
and preventing microtubule polymerization (8, 19, 30).
Paclitaxel, on the other hand, binds to microtubules and stabilizes
them, preventing the dynamic instability of microtubules needed for
normal functioning of the mitotic spindle apparatus (8, 19,
30).
In addition to cell cycle arrest, treatment of eukaryotic cells with
antimicrotubule agents also causes apoptosis. Apoptosis in
response to these agents is not simply a consequence of
G2/M arrest but appears to require phosphoregulatory
signaling mechanisms (9, 14, 24, 26, 28, 32). The c-Jun
N-terminal protein kinase (JNK) pathway is activated after treatment
with microtubule-disrupting agents (29, 33) and has been
shown to phosphorylate the antiapoptotic protein Bcl-2 in
response to paclitaxel and vinblastine (9, 24, 26, 28,
32). Overexpression of dominant-negative versions of kinases in
the JNK pathway has been shown to abolish Bcl-2 phosphorylation in
response to both paclitaxel and vinblastine treatment (9, 24,
32). Although there has been controversy as to whether Bcl-2
phosphorylation is protective or proapoptotic, most
mutational analyses of Bcl-2 indicate that Bcl-2 phosphorylation inactivates Bcl-2 (9, 21, 32). This suggests a model for paclitaxel-mediated apoptosis whereby the JNK pathway
phosphorylates Bcl-2, rendering the cell susceptible to
apoptosis. The JNK pathway or other pathways may also promote
cell death by activating the transcription of proapoptotic
genes or repressing the transcription of antiapoptotic
genes, since treatment of cells with antimicrotubule drugs has been
shown to modulate p53, Bak, Bcl-X, Bcl-2, and Bax expression (3,
18, 22, 23, 27). However, involvement of the JNK pathway in
apoptosis, mediated by antimicrotubule agents, has not been
conclusively demonstrated, since most of the studies supporting this
conclusion depended upon protein overexpression.
MEKK1, a mitogen-activated protein kinase kinase kinase
implicated in JNK signaling, is a 196-kDa protein that is activated by
chemoattractants such as formyl-Met-Leu-Phe in neutrophils (2), epidermal growth factor in epithelial cells
(10), and antigen ligation to immunoglobulin E (IgE)
receptor Fc
RI in mast cells (17). Overexpression
studies indicate that MEKK1 may be involved in the induction of
apoptosis. Treatment of cells with genotoxic agents and
prolonged suspension of adherent cells, which both result in
apoptosis, have been shown to cause caspase-dependent cleavage
of MEKK1 and activation of its kinase activity (5, 7, 12).
Overexpression of MEKK1 cleavage products has been shown to induce
apoptosis, while overexpression of kinase-inactive MEKK1 or
cleavage-resistant forms of MEKK1 inhibits apoptosis (5,
12). These data strongly suggest that MEKK1 is involved in both
genotoxin-induced cell death and cell death induced by the prolonged
suspension of adherent cells (anoikis).
A recent study with human leukemia HL-60 cells also suggests that MEKK1
is involved in antimicrotubule drug-mediated apoptosis. Overexpression of dominant-negative MEKK1 in these cells
prevented paclitaxel-induced JNK activation, Bcl-2 phosphorylation, and apoptosis (24). These data and evidence for a role
for MEKK1 in genotoxin-mediated apoptosis and anoikis strongly
suggest that MEKK1 may be a component of a signal transduction cascade
that promotes antimicrotubule drug-induced cell death. However,
recent studies with mekk1
/ mouse ES cells
have demonstrated that MEKK1 partially protects against
nocodazole-induced apoptosis (34). These
conflicting results raise the question of whether MEKK1 plays a
proapoptotic or protective role in microtubule
disruption-induced apoptosis. Using a somatic cell knockout
approach, we demonstrated that DT40 chicken bursal B cells deficient in
MEKK1 are defective in both vinblastine-mediated JNK activation and
apoptosis. Cycloheximide treatment of DT40 cells prevented
vinblastine-mediated cell death, indicating that vinblastine-mediated
cell death requires new protein synthesis. We also showed that
vinblastine-mediated apoptosis does not require
G2/M arrest, since arrest at the G1/S
transition prior to vinblastine treatment does not protect cells from
vinblastine-mediated apoptosis. Gene disruption of MEKK1
protected DT40 cells arrested at G1/S from
vinblastine-mediated apoptosis, suggesting that MEKK1 promotes apoptosis through a mechanism unrelated to the
G2/M checkpoint. These data indicate a critical role
for MEKK1 and new protein synthesis in vinblastine-mediated
apoptosis and suggest that vinblastine-mediated G2/M arrest and vinblastine-mediated apoptosis
occur independently of each other.
| |
MATERIALS AND METHODS |
Isolation of mekk1 genomic clones and construction of
mekk1 targeting constructs.
Genomic clones of
mekk1 were isolated from a 
GEM11 Leghorn chicken genomic
library by standard methods. An XhoI fragment of
approximately 18 kb from a genomic clone designated MEKK1 was subcloned
into pBluescript SK and restriction mapped. The location of the kinase
domain within MEKK1 was determined by Southern blotting using the cDNA
fragment 20E11, which contains the kinase domain. The
SmaI-EcoRI fragment at the 3' end of MEKK1 was
removed by truncation. The EcoRI-HpaI fragment,
which contains the kinase domain, was removed and replaced with the
linker
SphI-SacII-XbaI-BamHI. The
EcoRI site and the HpaI site were disrupted as a
consequence of linker ligation into the construct. For targeting
construct pMEKK1L
SB, a 2.5-kb neomycin resistance cassette was
subcloned at the introduced BamHI site. For targeting
construct pMEKK1LS, more genomic sequence was eliminated by removal
of a 2-kb SphI fragment. The Neor cassette was
then subcloned at the introduced BamHI site.
Cell lines and transfection.
DT40 cell lines were maintained
in DT40 medium (RPMI 1640 medium containing 10% fetal bovine serum,
1% chicken serum, 50 µM 2-mercaptoethanol, 50 U of penicillin
per ml, and 50 µg of streptomycin per ml) at a density of 0.5 × 106 to 1.5 × 106 cells/ml. In the
transfections of targeting constructs, DT40 cells in 0.5 ml of medium
were transferred to a 0.4-cm electroporation cuvette and pulsed at 550 V and 25 µF in the presence of 30 µg of the pMEKK1LSB or the
pMEKK1LS targeting construct linearized with KpnI.
Electroporated DT40 cells were then resuspended in 20 ml of DT40 medium
and plated on two 96-well plates at 5 × 104
cells/well. The transfected cells were selected with 2 mg of G418 per
ml (active concentration; Mediatech, Inc.).
Southern blot hybridization.
DT40 or
mekk1/ cells (1 × 107)
were lysed in 300 µl of lysis buffer (100 mM Tris [pH 8.5], 5 mM
EDTA, 0.2% sodium dodecyl sulfate [SDS], 200 mM NaCl, 100 µg of
proteinase K per ml) overnight at 55°C. Saturated NaCl solution (90 µl) was added to each tube, and the pellet was spun down. Genomic DNA
was ethanol precipitated from the supernatant and washed with 70%
ethanol. Genomic DNA (20 µg) for each sample was run on a 0.7%
agarose gel. The gel was transferred to nylon. Fragment NE and FR
probes were purified from a 1× TAE-0.7% agarose gel by using the
Geneclean II kit (Qbiogene, Inc.). Each fragment (50 ng) was labeled
with [
-32P]dCTP by using the Prime-It RmT random
primer labeling kit (Stratagene). Nylon filters were hybridized in FBI
buffer (1.5× SSPE [1× SSPE is 0.15 M NaCl, 10 mM
NaH2PO4, and 1 mM EDTA at pH 7.4], 7% SDS, 100 µg of salmon sperm DNA per ml, 10% [wt/vol] polyethylene
glycol 8000) at 65°C overnight. Nylon filters were successively
washed in 1× SSC (1× SSC is 0.15 M NaCl plus 0.015 M sodium
citrate)-0.1% SDS, 0.5× SSC-0.1% SDS, and 0.2× SSC-0.1% SDS for
30 min at 65°C and then exposed to X-ray film.
Western blot analysis.
For MEKK1 Western blotting,
107 DT40 or mekk1/ cells were
spun down and lysed in 150 µl of 1× SDS loading dye (50 mM Tris [pH 6.8], 2% SDS, 0.1% bromophenol blue, 10% glycerol, 5%
2-mercaptoethanol). Samples were sonicated, boiled for 5 min, and run
on an SDS-7% polyacrylamide gel electrophoresis (PAGE) separating
gel. The SDS-PAGE gel was transferred to nitrocellulose by using a
Bio-Rad Trans-Blot semidry transfer apparatus. The nitrocellulose
membrane was incubated with a 1:1,000 dilution of polyclonal rabbit
anti-MEKK1 serum (PharMingen International), followed with a 1:3,000
dilution of goat anti-rabbit IgG-horseradish paroxidase. For the JNK
Western blot assay, 25 µg of total protein for each sample was loaded on an SDS-10% PAGE separating gel. The blot was incubated with a
1:1,000 dilution of an anti-JNK (C17) antibody (Santa Cruz
Biotechnology, Inc.), followed with a 1:3,000 dilution of anti-goat
IgG-horseradish peroxidase (Santa Cruz Biotechnology, Inc.).
JNK in vitro kinase assays.
DT40 or
mekk1/ cells (1.5 × 107)
were incubated in DT40 medium alone (30 min), anti-IgM (15 min), 50 ng
of phorbol myristate acetate (PMA) per ml-250 ng of ionomycin per ml
(30 min), 1 µg of nocodazole per ml (30 min), 1 µM paclitaxel (30 min), and 1 µM vinblastine sulfate (30 min) at 37°C. Cells were
washed once with ice-cold phosphate-buffered saline and lysed in 800 µl of modified radioimmunoprecipitation assay buffer (50 mM Tris [pH 7.5], 150 mM NaCl, 1% Igepal CA-630, 0.25% sodium deoxycholate, 1 mM
EGTA, 5 mM NaF, 1 µg of leupeptin per ml, 1 µg of
aprotinin per ml, 1 mM sodium vanadate, 1 mM phenylmethyl
sulfonyl fluoride) on ice for 30 min with periodic agitation. The total
protein concentration of each cytoplasmic extract was determined by
using the Bio-Rad protein assay. For each sample, 300 µg of total
protein was used in each JNK in vitro kinase assay, which was performed
as previously described (16). To quantitate JNK in vitro
kinase assay results, gels were scanned by using the Molecular Dynamics
STORM 860 PhosphorImager, and integrated band intensities were obtained
by using Molecular Dynamics ImageQuant software. Local average
background correction was used to correct for the background, and
volume values were used to calculate fold activation over untreated cells.
Analysis of cytotoxicity and apoptosis.
The CytoTox
nonradioactive cytotoxicity assay kit from Promega was used for all
cytotoxicity assays. Wild-type DT40 or
mekk1/ cells (5 × 104 in
each well) were plated on 96-well plates. Experiments were performed in
accordance with the Promega protocol, except that 20 µl of
supernatant or medium samples diluted to 50 µl with
phosphate-buffered saline were used in the assay instead of 50 µl of
undiluted samples. All experiments were performed in triplicate.
A492 readings were taken on a plate reader.
Percent cytotoxicity was calculated as follows: % cytotoxicity = 100 × (A492 of treated cell 
A492 of medium alone)/(A492 after complete
lysis A492 of medium alone).
In DNA laddering assays, 7.5 × 106 DT40 or
mekk1/ cells at a density of 5 × 105/ml were treated for the indicated times
with 1 µM vinblastine sulfate, 12.5 µM etoposide, 4 mM thymidine,
50 µg of cycloheximide per ml, or combinations of these agents and
then processed as previously described (15). In the
caspase 3 activity assay, 2 × 107 cells treated for
the indicated times with 1 µM vinblastine sulfate were lysed in 50 µl of ice-cold cell lysis buffer containing 50 mM HEPES (pH
7.4), 100 mM NaCl, 0.1%
3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate (CHAPS),
1 mM dithiothreitol, and 0.1 mM EDTA, flash frozen in an
ethanol-dry ice bath, and stored at 70°C before use. Caspase 3 activity assay experiments were performed as described in the Calbiochem protocol for colorimetric caspase 3 substrate I
(Ac-DEVD-
NA). A405 readings were taken on a
plate reader at 10-min intervals.
Analysis of cell cycle.
For each experimental sample,
106 DT40 or MC2 cells at a density of 5 × 105/ml were treated for the indicated times with 1 µM
vinblastine sulfate. Cells were then spun down and resuspended in 4°C
hypotonic DNA staining buffer (3.4 mM sodium citrate, 0.3% Triton
X-100, 150 µM propidium iodide, 20 µg of RNase A per ml). Samples
were incubated at 4°C for 30 min to 1 h, followed by cell cycle
analysis on a FACScalibur (Becton Dickinson, Inc.) flow cytometer.
| |
RESULTS |
Establishment of mekk1/ cell lines in
DT40 cells.
We isolated a 1.2-kb cDNA that was homologous to the
mammalian MEKK1 kinase domain from a concanavalin A-stimulated chicken T-cell cDNA library in vector pCDNA3. Additional sequence was isolated
through the PCR amplification of more 5' sequence from the T-cell cDNA
library. Amino acid sequence comparisons between the putative chicken
MEKK1 kinase domain and the human and mouse MEKK1 kinase domains
(residues 1221 to 1493 of the mouse sequence) indicated that the
isolated sequence is approximately 97% identical to the mammalian
MEKK1 kinase domain. In contrast, the putative chicken MEKK1 kinase
domain is approximately 40% identical to human MEKK2 and MEKK3,
indicating that it is indeed an MEKK1 homolog. A genomic sequence was
subsequently isolated that contained kinase domain sequence.
To determine the role of MEKK1 in bursal B-cell line DT40, the
mekk1 locus was disrupted by homologous recombination. DT40 cells were transfected with either the pMEKK1LSB or the pMEKK1LS targeting construct (Fig. 1A). These
targeting constructs disrupt the C-terminal MEKK1 kinase domain. The
pMEKK1LSB and pMEKK1LS targeting constructs remove a region of
MEKK1 homologous to amino acids 1206 to 1447 and 1312 to 1447 of human
MEKK1, respectively. Transfected cells were plated on 96-well plates,
and G418-resistant clones were isolated. Disruption of the
mekk1 locus in each of the individual clones was assessed by
genomic Southern blotting using fragment NE as a probe (Fig. 1A).
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FIG. 1.
Targeting constructs for disruption of the MEKK1 kinase
domain and confirmation of gene disruption. (A) (i) For targeting
construct pMEKK1LSB, the EcoRI-HpaI fragment,
which contains the kinase domain (see ii), was removed and replaced
with the linker
SphI-SacII-XbaI-BamHI. The
EcoRI and HpaI sites were both disrupted as a
result of linker ligation. A 2.5-kb neomycin resistance cassette was
then subcloned into the BamHI site. (ii) Partial restriction
map of the mekk1 genomic region containing the MEKK1 kinase
domain. FR is a PCR product spanning two exons, and its sequence is
contained within the region deleted in the two targeting constructs
shown in i and iii. NE is an NcoI-EcoRI fragment
that was used in the initial genomic Southern screen for gene
disruption at the mekk1 locus. (iii) Targeting construct
pMEKK1LS is similar to pMEKK1LSB, except that the SphI
fragment 5' of the Neo cassette has been removed. The 10-kb bar above
the targeting construct indicates the size of the EcoRI
fragment at the endogenous mekk1 locus (see ii). The 7-kb
bar above the targeting constructs indicates the size of the
EcoRI-BamHI fragment at the mekk1
locus disrupted with the pMEKK1LSB or pMEKK1LS targeting
construct. (B) DNAs from wild-type DT40 cells (20 µg) and MEKK1
knockout cell lines MC1, MC2, and MC3 were digested with
EcoRI (E) and EcoRI-BamHI (E+B) and
run on a 0.7% agarose gel in duplicate. The gel was transferred to a
nylon filter, which was subsequently cut to obtain two duplicate
filters. One filter was hybridized with fragment NE, and the other
filter was hybridized with fragment FR. (C) Whole-cell extracts were
prepared for 293T cells, wild-type DT40 cells, and MEKK1 knockout cell
lines as described in Materials and Methods. Each extract (30 µl) was
loaded. The Western blot was probed with an anti-MEKK1 antibody.
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MEKK1-positive clone 1 (MC1) and MC3 were generated by using
pMEKK1LSB, while MC2 was generated by using pMEKK1LS. Southern blotting results for MC1, MC2, and MC3 indicated that mekk1
is hemizygous in DT40 cells. Isolated clones showed only the expected 7-kb BamHI-EcoRI knockout band, as well as a
>10-kb EcoRI knockout band, after one round of G418
selection (Fig. 1B). The 10-kb wild-type band is missing from all of
the positive clones tested (Fig. 1B and data not shown). To confirm
that the mekk1 locus is hemizygous, additional Southern
blots were performed by using fragment FR, which is derived from the
region deleted in the MEKK1 targeting constructs (Fig. 1A).
Fragment FR hybridized to the expected 10-kb BamHI-EcoRI and 10-kb EcoRI bands in
the wild-type DT40 DNA control lanes but did not hybridize in the
knockout genomic DNA lanes (Fig. 1B), indicating that DT40 cells
contain only one copy of the mekk1 gene and that this copy
was disrupted in one round of homologous recombination.
To determine whether gene disruption of the MEKK1 kinase domain affects
the MEKK1 protein, Western blots were performed by using an antibody
against the C terminus of human MEKK1. Wild-type DT40 and control 293T
extracts showed a triplet of approximately 196 kDa that was not present
in the MC1, MC2, and MC3 extracts (Fig. 1C), indicating that expression
of at least the MEKK1 kinase domain had been abolished in these
knockout cell lines. Northern blot results obtained by using fragment
FR as a probe corroborated the Western blotting data (data not shown).
JNK activation in DT40 cells after stimulation with
microtubule-disrupting agents is abolished in
mekk1/ clones.
MEKK1 is a
mitogen-activated protein kinase kinase kinase in the JNK
cascade. Disruption of mekk1 by homologous recombination should therefore abolish JNK activation for a subset of JNK-activating stimuli. To determine whether the mekk1/
DT40 clones have a defect in JNK activation, in vitro JNK kinase assays
were performed. Stimulation of wild-type DT40 cells with the
microtubule-disrupting agents nocodazole, vinblastine, and paclitaxel
caused a marked increase in JNK activity (Fig.
2A). In contrast, JNK activity after
treatment with microtubule-disrupting agents was completely abolished
in mekk1/ DT40 cell lines MC1, MC2, and MC3
(Fig. 2A). Anti-JNK Western blots showed that roughly equivalent
amounts of JNK were present in the extracts used for
immunoprecipitation (Fig. 2A). The same defect was seen in all of the
other mekk1/ cell lines tested (data not
shown). Results from three separate in vitro JNK kinase assays were
quantified, and average values were determined. The defect in JNK
activation in mekk1/ cells is specific for
microtubule-disrupting agents, since JNK activation following
PMA-ionomycin and anti-IgM stimulation was unaffected (Fig. 2A and B).
MEKK1 appears to function specifically in antimicrotubule drug-induced
JNK activation, since mekk1 kinase domain disruption had no
effect on vinblastine- or PMA-ionomycin-induced NF-
B, p38, and ERK
activation (data not shown).
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FIG. 2.
JNK activation in DT40 cells after stimulation with
microtubule-disrupting agents is abolished in
mekk1/ cell lines MC1, MC2, and MC3. (A)
DT40, MC1, MC2, and MC3 cells were incubated in DT40 medium alone (30 min), anti-IgM (15 min), 50 ng of PMA per ml-250 ng of ionomycin per
ml (30 min), 1 µg of nocodazole (noc.) per ml (30 min), 1 µM
paclitaxel (pac.) (30 min), and 1 µM vinblastine sulfate (vin.) (30 min) at 37°C. Cells were subsequently lysed in modified
radioimmunoprecipitation assay buffer, and 300 µg of total protein
from each extract was used in a JNK in vitro kinase assay as described
in Materials and Methods. For the JNK Western blot assay, 25 µg of
total protein from each extract was subjected to SDS-PAGE. The filter
was incubated with an anti-JNK (C17) antibody. (B) Three separate JNK
in vitro kinase assays were performed, and results were quantitated as
described in Materials and Methods. Results are expressed as fold
activation over untreated cells. Average values are shown.
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Cell death induced by microtubule-disrupting agents is abrogated in
mekk1/ cell lines.
Since the JNK
pathway has been implicated in apoptosis induced by
microtubule-disrupting agents, mekk1/ cell
lines were tested in cytotoxicity assays after exposure to vinblastine
and nocodazole. In cytotoxicity assays, increasing concentrations of
vinblastine caused increasing levels of cytotoxicity in wild-type DT40
cells (Fig. 3A). In
mekk1/ cell lines MC1, MC2, and MC3,
however, increasing concentrations of vinblastine had no effect on
cytotoxicity (Fig. 3A). Identical results were obtained by using
nocodazole (data not shown). This defect in cell death is specific for
the cytotoxicity induced by microtubule-disrupting agents, since
cytotoxicity in response to etoposide (Fig. 3B) and doxorubicin (data
not shown) was unimpaired in the MC2 cell line.
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FIG. 3.
Cell death induced by microtubule-disrupting agents is
abrogated in mekk1/ cell lines. The CytoTox
nonradioactive cytotoxicity assay kit from Promega was used for all
cytotoxicity assays. Wild-type DT40, MC1, MC2, and MC3 cells (5 × 104 per well) were plated on a 96-well plate. (A) In the
vinblastine dose-response experiment, vinblastine was titrated into the
wells at concentrations of 0 to 1 µM. (B) In the etoposide
dose-response experiment, etoposide was titrated into the wells at
concentrations of 781 nM, 3.13 µM, and 25 µM. Plates for both
dose-response experiments were incubated for approximately 16 h at
37°C. The cytotoxicity assay was performed as described in Materials
and Methods.
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The difference in vinblastine-mediated cytotoxicity between
wild-type and mekk1/ DT40 cells is due to a
defect in vinblastine-mediated apoptosis.
To determine
whether the difference in vinblastine-mediated cytotoxicity between
wild-type and mekk1/ cells is due to an
apoptosis defect in the mekk1 knockout cell lines,
apoptosis assays were performed. In DNA laddering assays, wild-type DT40 cells exhibited DNA laddering indicative of
apoptosis after 6 and 8 h of vinblastine treatment (Fig.
4A). MC2 cells showed no DNA laddering
after 2, 6, or 8 h of vinblastine treatment (Fig. 4A). In contrast,
etoposide induced apoptosis equally well in wild-type DT40
cells and MC2 cells (Fig. 4A).
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FIG. 4.
The difference in vinblastine-mediated cytotoxicity
between wild-type and mekk1/ DT40 cells is
due to a defect in vinblastine-mediated apoptosis. (A) In DNA
laddering assays, 7.5 × 106 DT40 or MC2 cells were
treated for 2, 6, or 8 h with 1 µM vinblastine sulfate, for 3.5 h with 12.5 µM etoposide, or for 8 h with DT40 medium alone.
DNAs from these samples were prepared as described in Materials and
Methods. The equivalent of 3.75 × 106 cells of each
sample was run on a 1% agarose gel. (B) In the caspase 3 activity
assay, 2 × 107 cells were treated for 2 or 8 h
with 1 µM vinblastine sulfate or for 8 h with DT40 medium alone
(0 h) and then lysed in 50 µl of ice-cold cell lysis buffer. Extracts
were incubated at 37°C with the caspase 3 substrate
Ac-DEVD-NA. A405 readings were taken on a
plate reader at 10-min intervals. A405 readings
(relative caspase activity) at 120 min are shown.
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These results were recapitulated in caspase 3 activity assays. Extracts
prepared from DT40 cells treated for 8 h with vinblastine showed a
marked increase in caspase 3 activity in comparison with untreated cell
extracts (Fig. 4B). On the other hand, extracts prepared from MC2 cells
treated for 8 h with vinblastine showed no increase in caspase 3 activity compared with untreated MC2 cells (Fig. 4B). These data
indicate that MEKK1 promotes apoptosis through a caspase
3-dependent signal transduction pathway.
mekk1-null DT40 cells remain arrested at
G2/M, but wild-type DT40 cells undergo apoptosis
after 8 h of vinblastine treatment.
Microtubule-disrupting
agents cause cell cycle arrest at M phase. To determine whether there
is a difference in the cell cycle profiles of vinblastine-treated DT40
and MC2 cells that might explain the apoptosis defect in MC2
cells, the cell cycle profiles of wild-type DT40 and MC2 cells were
taken after 2 to 24 h of vinblastine treatment. Untreated DT40 and
MC2 cells had similar cell cycle profiles (Fig.
5). In both wild-type DT40 and MC2 cells, vinblastine treatment resulted in accumulation of cells at the G2/M transition after 6 h of treatment (Fig. 5),
indicating that MEKK1 is not required for vinblastine-mediated cell
cycle arrest at the G2/M transition. The increase in the
size of the sub-G1 peak (Fig. 5 and
6A) and the decrease in the percentage of
wild-type DT40 cells in G2/M phase suggested that the
wild-type DT40 cells started to undergo apoptosis by 8 h of vinblastine treatment. Unlike wild-type DT40 cells,
vinblastine-treated MC2 cells remained blocked at the G2/M
transition for 8 to 24 h, with a much less pronounced decrease in
cell viability (Fig. 5 and 6A). These results indicate that
abrogation of vinblastine-mediated apoptosis by mekk1 gene disruption does not occur through modulation of
cell cycle progression and that vinblastine-mediated apoptosis
is not simply a consequence of prolonged G2/M arrest.
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FIG. 5.
mekk1-null DT40 cells remain arrested at
G2/M after prolonged vinblastine treatment, but wild-type
DT40 cells undergo apoptosis after 8 h of vinblastine
treatment. DT40 or MC2 cells (106) were treated for 6 or
8 h with 1 µM vinblastine sulfate or for 8 h with DT40
medium alone. Cells were stained in hypotonic DNA staining buffer and
analyzed as described in Materials and Methods.
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FIG. 6.
Vinblastine (vin.)-mediated cell death in DT40 cells
does not depend on G2/M arrest. (A) DT40 or MC2 cells
(106) were either pretreated with 4 mM thymidine (6 h) or
left untreated (6 h). After the initial 6-h incubation, 1 µM
vinblastine was added to designated samples. The treated cells were
further incubated for 6 or 12 h, and cell cycle analysis was
performed as described in Materials and Methods. Treatments were
staggered over an 18-h period so that all samples could be processed at
the same timepoint. (B) DT40 or MC2 cells (5 × 104)
were plated in each well of a 96-well plate. Two duplicate sets of
thymidine titrations were performed for both DT40 and MC2 cells at
thymidine concentrations of 0, 1, 2, and 4 µM. Plates (96 wells) were
incubated for 6 h at 37°C. Vinblastine was then added at a
concentration of 1 µM into one set of thymidine titrations for both
DT40 and MC2 cells, and the cells were further incubated for 12 h.
A cytotoxicity assay was performed on treated cells as described in
Materials and Methods.
|
|
Vinblastine-mediated cell death in DT40 cells does not depend on
G2/M arrest.
It has been postulated that
G2/M arrest is required for microtubule-disrupting
agent-mediated apoptosis (32). To test this hypothesis, we decided to block DT40 cells at G1 or S phase
prior to vinblastine treatment. Cell cycle analysis was first
performed to determine if thymidine and L-mimosine can
block DT40 cells at S phase and G1 phase, respectively.
Cell cycle analysis indicated that over 80% of DT40 cells were
arrested at G1/S following 6 to 18 h of treatment with
4 mM thymidine (Fig. 6A).
Addition of 1 µM vinblastine to DT40 cells pretreated for 6 h
with 4 mM thymidine resulted in an increase in the sub-G1
fraction (apoptotic cells) to over 50% of the total cells
after 12 h of treatment, similar to DT40 cells treated with 1 µM
vinblastine alone. Cytotoxicity assays were subsequently performed on
DT40 cells treated with thymidine, vinblastine, or thymidine plus
vinblastine. DT40 cells treated with thymidine alone exhibited low
levels of cytotoxicity that increased slightly with increasing
thymidine concentrations (Fig. 6B). DT40 cells treated with 1 µM
vinblastine alone exhibited approximately 60% cytotoxicity (Fig. 6B).
Arrest of DT40 cells at G1/S with thymidine prior to
addition of 1 µM vinblastine had no effect on vinblastine-mediated
cytotoxicity (Fig. 6B), indicating that G2/M arrest is not
required for vinblastine-mediated apoptosis. MEKK1 deficiency
was still able to protect MC2 cells blocked at G1/S with
thymidine from vinblastine-mediated apoptosis (Fig. 6B),
suggesting that MEKK1 acts independently of the G2/M checkpoint to promote vinblastine-mediated apoptosis. These
results were recapitulated with the G1 phase blocker
L-mimosine (data not shown).
Vinblastine-mediated cell death in DT40 cells is dependent on new
protein synthesis.
If the role of MEKK1 in vinblastine-mediated
apoptosis is to activate the transcription of genes necessary
for apoptosis, blocking of transcription or new protein
synthesis in vinblastine-treated DT40 cells should attenuate the
apoptotic response. To investigate this possibility,
vinblastine-treated DT40 cells were treated with increasing
concentrations of cycloheximide. DT40 cells treated with various
concentrations of cycloheximide alone exhibited a percentage of
cytotoxicity comparable to that of untreated cells (Fig.
7A), and DT40 cells treated with
vinblastine alone exhibited approximately 80% cytotoxicity (Fig. 7A).
In contrast, vinblastine-treated cells exhibited a decreasing
percentage of cytotoxicity with increasing concentrations of
cycloheximide (Fig. 7A). At a cycloheximide concentration of 50 µg/ml, vinblastine-treated DT40 cells exhibited a percentage of
cytotoxicity equivalent to that of DT40 cells treated with 50 µg of
cycloheximide per ml alone (Fig. 7A). Cycloheximide inhibited
vinblastine-induced DNA laddering (Fig. 7B) and caspase 3 activity
(data not shown) in DT40 cells, indicating that it specifically
inhibited apoptosis. These data indicate that new protein
synthesis, initiated by a MEKK1-dependent pathway or other pathways, is
required for vinblastine-mediated apoptosis.
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|
FIG. 7.
Vinblastine (vin.)-mediated cell death in DT40 cells is
dependent on new protein synthesis. (A) DT40 cells (5 × 104) were plated in each well of a 96-well plate. Two
duplicate sets of cycloheximide (CHX) titrations were performed at
cycloheximide concentrations of 0, 3.13, 12.5, 50, and 100 µg/ml. In
one set of cycloheximide titrations, vinblastine was added at a
concentration of 1 µM. The CytoTox nonradioactive cytotoxicity assay
was performed as described in Materials and Methods. Shown are the
effects of increasing concentrations of cycloheximide on DT40 cells
alone and on DT40 cells treated with 1 µM vinblastine. (B) In the DNA
laddering assay, 7.5 × 106 DT40 or MC2 cells were
treated as follows. For vinblastine stimulations, cells were stimulated
at a concentration of 1 µM (8 h). For thymidine (thy.) experiments,
cells were pretreated for 6 h in 4 mM thymidine with or without
subsequent addition of 1 µM vinblastine (8 h). For cycloheximide
experiments, cells were treated at a concentration of 50 µg/ml (8 h).
Treatments were staggered over a 14-h period so that all samples could
be processed at the same time.
|
|
| |
DISCUSSION |
Antimicrotubule agents cause both G2/M arrest and
apoptosis in eukaryotic cells. Because G2/M arrest
precedes apoptosis (19, 25), it has been thought
that antimicrotubule agent-induced apoptosis requires
G2/M arrest. Previous studies have shown that Bcl-2 is
inactivated at G2/M through JNK-dependent phosphorylation (32). Based on these observations, it has been postulated
that antimicrotubule agents kill cells by arresting them at
G2/M, thus keeping them in a state of prolonged
sensitization to apoptosis through the
phosphorylation-dependent inactivation of Bcl-2. However, a requirement
for G2/M arrest in antimicrotubule agent-mediated apoptosis has not been conclusively demonstrated.
In this study, we showed that vinblastine-mediated apoptosis in
DT40 cells does not depend on G2/M arrest. DT40 cells
arrested at G1/S by thymidine or L-mimosine
treatment are still sensitive to vinblastine-mediated apoptosis
to the same extent as G2/M-arrested cells. In addition, we
showed that new protein synthesis is required for vinblastine-mediated
apoptosis. Cycloheximide (50 µg/ml) completely suppressed
vinblastine-mediated cytotoxicity in DT40 cells. These data lend
support to a model in which one or more signaling pathways, independent
of G2/M arrest, promote antimicrotubule drug-induced apoptosis by activating the transcription of
proapoptotic genes.
We demonstrated that MEKK1 is a component of a signaling pathway that
is necessary for nocodazole- and vinblastine-mediated cell death. The
results of our gene disruption experiments indicate that MEKK1 is
required for vinblastine- and nocodazole-mediated apoptosis but
not for etoposide- and doxorubicin-mediated apoptosis. mekk1 gene disruption had no effect on cell cycle
progression and vinblastine-mediated G2/M arrest,
indicating that MEKK1 is specifically involved in vinblastine-mediated
apoptosis. We also showed that mekk1 gene disruption
protects DT40 cells arrested at G1/S from
vinblastine-mediated apoptosis, suggesting that MEKK1 promotes
apoptosis independently of vinblastine-mediated
G2/M arrest. However, our data contradict the results of an
independently produced MEKK1 knockout. In these studies,
mekk1 gene disruption sensitizes ES cells to
nocodazole-mediated apoptosis (34). The discrepancy between our results and results from ES cell studies indicates that different cell types have different mechanisms for
antimicrotubule drug-mediated apoptosis. Indeed, the JNK
pathway, of which MEKK1 is a component, has been implicated in both
cell survival and apoptosis (6). It is possible
that DT40 cells require MEKK1 for antimicrotubule drug-mediated
apoptosis, while ES cells are partially protected from
antimicrotubule drug-mediated apoptosis by MEKK1.
Consistent with results from two independently generated MEKK1
knockouts, we also demonstrated that mekk1 gene disruption prevents vinblastine-, paclitaxel-, and nocodazole-mediated JNK activation but has no effect on p38, ERK, and NF-B activation in
response to these stimuli (31, 34, 35). The JNK activation defect is specific for antimicrotubule drug stimulation, since PMA-ionomycin-mediated JNK activation was not affected by
mekk1 gene disruption. Moreover, we showed that MEKK1 is not
required for anti-IgM-mediated JNK activation.
The current study does not address the question of which signaling
pathways downstream of MEKK1 are involved in apoptosis in
response to treatment with antimicrotubule agents. Based on the fact
that JNK is specifically activated by MEKK1 during microtubule disruption, JNK is likely to be involved in MEKK1-mediated
apoptosis. One possible mechanism by which MEKK1 mediates
apoptosis in response to antimicrotubule agents is the
JNK-dependent phosphorylation and concomitant inactivation of Bcl-2.
Previous studies have shown that Bcl-2 is phosphorylated in response to
microtubule disorganization and that overexpression of
dominant-negative MEKK1 or JNK1 inhibits paclitaxel-induced Bcl-2
phosphorylation and apoptosis (9, 14, 24, 27, 28,
32). The phosphorylation sites have been mapped to the serine
residues at positions 70 and 87 of human Bcl-2, and mutated Bcl-2 with
alanine substitutions at these phosphorylation sites shows an enhanced
ability to protect against apoptosis (32). We
compared the human and chicken Bcl-2 amino acid sequences and found
that these two human Bcl-2 phosphorylation sites are not conserved in
chicken Bcl-2. Nevertheless, this result does not preclude the
possibility that chicken Bcl-2 is phosphorylated at alternate sites.
Another possible mechanism by which MEKK1 promotes apoptosis in
DT40 cells is transcriptional up-regulation of proapoptotic genes. We showed that both MEKK1 and new protein synthesis play a
critical role in vinblastine-induced apoptosis. This hypothesis is further supported by data from prostate cancer cells, in which overexpression of a dominant-active version of MEKK1 activates the transcription of androgen receptor-regulated genes and
promotes apoptosis (1). Moreover,
apoptosis in T-lymphocytes in response to stress stimuli occurs
through the JNK-dependent transcriptional up-regulation of Fas ligand
and overexpression of dominant-negative MEKK1 inhibits these events
(11, 20). In addition, increased expression of
proapoptotic molecules such as p53 and Bax and decreased expression of antiapoptotic molecules such as Bcl-x and
Bcl-2 in response to paclitaxel treatment have also been observed
(3, 18, 22, 23, 27). These observations strongly suggest a role for MEKK1 in the transcriptional up-regulation of
proapoptotic genes in response to antimicrotubule agents.
However, the exact mechanisms for MEKK1-mediated apoptosis
remain to be elucidated.
Antimicrotubule agents represent a major class of
chemotherapeutic drugs. The demonstration of MEKK1 as an essential
kinase involved in antimicrotubule agent-mediated apoptosis
should provide valuable information for further improvements in cancer
chemotherapy. One may screen for MEKK1-specific small
molecules to enhance MEKK1-mediated apoptosis in cancer cells
without affecting normal cell proliferation. In addition,
down-regulation of MEKK1 or kinases downstream of MEKK1 may represent a
potential mechanism for the development of chemoresistance.
| |
ACKNOWLEDGMENTS |
This work was supported by National Institute of General Medical
Sciences grant GM57559 and by The Leukemia & Lymphoma Society. R. Kwan
was supported by National Cancer Institute National Research Service
Award grant CA09056.
We thank Paul Dempsey for assistance with flow cytometry. We thank C. Sawyers and members of the Cheng laboratory for useful discussions and
critical review of the manuscript.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology, Immunology & Molecular Genetics, 8-240J Factor, UCLA, Los Angeles, CA 90095-1781. Phone: (310) 825-8896. Fax: (310) 206-5553. E-mail: genhongc{at}microbio.ucla.edu.
| |
REFERENCES |
| 1.
|
Abreu-Martin, M. T.,
A. Chari,
A. A. Palladino,
N. A. Craft, and C. L. Sawyers.
1999.
Mitogen-activated protein kinase kinase kinase 1 activates androgen receptor-dependent transcription and apoptosis in prostate cancer.
Mol. Cell. Biol.
19:5143-5154[Abstract/Free Full Text].
|
| 2.
|
Avdi, N. J.,
B. W. Winston,
M. Russel,
S. K. Young,
G. L. Johnson, and G. S. Worthen.
1996.
Activation of MEKK by formyl-methionyl-leucyl-phenylalanine in human neutrophils. Mapping pathways for mitogen-activated protein kinase activation.
J. Biol. Chem.
271:33598-33606[Abstract/Free Full Text].
|
| 3.
|
Blagosklonny, M. V.,
T. W. Schulte,
P. Nguyen,
E. G. Mimnaugh,
J. Trepel, and L. Neckers.
1995.
Taxol induction of p21WAF1 and p53 requires c-raf-1.
Cancer Res.
55:4623-4626[Abstract/Free Full Text].
|
| 4.
|
Burke, D. J.
2000.
Complexity in the spindle checkpoint.
Curr. Opin. Genet. Dev.
10:26-31[CrossRef][Medline].
|
| 5.
|
Cardone, M. H.,
G. S. Salvesen,
C. Widmann,
G. Johnson, and S. M. Frisch.
1997.
The regulation of anoikis: MEKK-1 activation requires cleavage by caspases.
Cell
90:315-323[CrossRef][Medline].
|
| 6.
|
Davis, R. J.
2000.
Signal transduction by the JNK group of MAP kinases.
Cell
103:239-252[CrossRef][Medline].
|
| 7.
|
Deak, J. C.,
J. V. Cross,
M. Lewis,
Y. Qian,
L. A. Parrott,
C. W. Distelhorst, and D. J. Templeton.
1998.
Fas-induced proteolytic activation and intracellular redistribution of the stress-signaling kinase MEKK1.
Proc. Natl. Acad. Sci. USA
95:5595-5600[Abstract/Free Full Text].
|
| 8.
|
Downing, K. H.
2000.
Structural basis for the interaction of tubulin with proteins and drugs that affect microtubule dynamics.
Annu. Rev. Cell Dev. Biol.
16:89-111[CrossRef][Medline].
|
| 9.
|
Fan, M.,
M. Goodwin,
T. Vu,
C. Brantley-Finley,
W. A. Gaarde, and T. C. Chambers.
2000.
Vinblastine-induced phosphorylation of Bcl-2 and Bcl-XL is mediated by JNK and occurs in parallel with inactivation of the Raf-1/MEK/ERK cascade.
J. Biol. Chem.
275:29980-29985[Abstract/Free Full Text].
|
| 10.
|
Fanger, G. R.,
N. L. Johnson, and G. L. Johnson.
1997.
MEK kinases are regulated by EGF and selectively interact with Rac/Cdc42.
EMBO J.
16:4961-4972[CrossRef][Medline].
|
| 11.
|
Faris, M.,
K. M. Latinis,
S. J. Kempiak,
G. A. Koretzky, and A. Nel.
1998.
Stress-induced Fas ligand expression in T cells is mediated through a MEK kinase 1-regulated response element in the Fas ligand promoter.
Mol. Cell. Biol.
18:5414-5424[Abstract/Free Full Text].
|
| 12.
|
Gibson, S.,
C. Widmann, and G. L. Johnson.
1999.
Differential involvement of MEK kinase 1 (MEKK1) in the induction of apoptosis in response to microtubule-targeted drugs versus DNA damaging agents.
J. Biol. Chem.
274:10916-10922[Abstract/Free Full Text].
|
| 13.
|
Gimenez-Abian, J. F., and D. J. Clarke.
2000.
Checkpoints controlling mitosis.
Bioessays
22:351-363[CrossRef][Medline].
|
| 14.
|
Haldar, S.,
N. Jena, and C. M. Croce.
1995.
Inactivation of Bcl-2 by phosphorylation.
Proc. Natl. Acad. Sci. USA
92:4507-4511[Abstract/Free Full Text].
|
| 15.
|
Herrmann, M.,
H. Lorenz,
R. Voll,
M. Grunke,
W. Woith, and J. Kalden.
1994.
A rapid and simple method for the isolation of apoptotic DNA fragments.
Nucleic Acids Res.
22:5506-5507[Free Full Text].
|
| 16.
|
Hibi, M.,
A. Lin,
T. Smeal,
A. Minden, and M. Karin.
1993.
Identification of an oncoprotein- and UV-responsive protein kinase that binds and potentiates the c-Jun activation domain.
Genes Dev.
7:2135-2148[Abstract/Free Full Text].
|
| 17.
|
Ishizuka, T.,
A. Oshiba,
N. Sakata,
N. Terada,
G. L. Johnson, and E. W. Gelfand.
1996.
Aggregation of the FcRI on mast cells stimulates c-Jun amino-terminal kinase activity.
J. Biol. Chem.
271:12762-12766[Abstract/Free Full Text].
|
| 18.
|
Jones, N. A.,
J. Turner,
A. J. McIlwrath,
R. Brown, and C. Dive.
1998.
Cisplatin and paclitaxel-induced apoptosis of ovarian carcinoma cells and the relationship between bax and bak up-regulation and the functional status of p53.
Mol. Pharmacol.
53:819-826[Abstract/Free Full Text].
|
| 19.
|
Jordan, M. A., and L. Wilson.
1998.
Microtubules and actin filaments: dynamic targets for cancer chemotherapy.
Curr. Opin. Cell Biol.
10:123-130[CrossRef][Medline].
|
| 20.
|
Kasibhatla, S.,
T. Brunner,
L. Genestier,
F. Echeverri,
A. Mahboubi, and D. R. Green.
1998.
DNA damaging agents induce expression of Fas ligand and subsequent apoptosis in T lymphocytes via the activation of NF-kappa B and AP-1.
Mol. Cell. Biol.
1:543-551.
|
| 21.
|
Ling, Y.,
C. Tornos, and R. Perez-Soler.
1998.
Phosphorylation of bcl-2 is a marker of M phase events and not a determinant of apoptosis.
J. Biol. Chem.
273:18984-18991[Abstract/Free Full Text].
|
| 22.
|
Liu, Q., Y., and C. A. Stein.
1997.
Taxol and estramustine-induced modulation of human prostate cancer cell apoptosis via alteration in bcl-xL and bak expression.
Clin. Cancer Res.
3:2039-2046[Abstract].
|
| 23.
|
Moos, P. J., and F. A. Fitzpatrick.
1998.
Taxane-mediated gene induction is independent of microtubule stabilization: induction of transcription regulators and enzymes that modulate inflammation and apoptosis.
Proc. Natl. Acad. Sci. USA
95:3896-3901[Abstract/Free Full Text].
|
| 24.
|
Shiah, S.,
S. Chuang, and M. Kuo.
2001.
Involvement of Asp-Glu-Val-Asp-directed, caspase-mediated mitogen-activated protein kinase kinase 1 cleavage, c-Jun N-terminal kinase activation, and subsequent Bcl-2 phosphorylation for paclitaxel-induced apoptosis in HL-60 cells.
Mol. Pharmacol.
59:254-262[Abstract/Free Full Text].
|
| 25.
|
Sorger, P. K.,
M. Dobles,
R. Tournebize, and A. A. Hyman.
1997.
Coupling cell division and cell death to microtubule dynamics.
Curr. Opin. Cell Biol.
9:807-814[CrossRef][Medline].
|
| 26.
|
Srivastava, R. K.,
A. R. Srivastava,
S. J. Korsmeyer,
M. Nesterova,
Y. S. Cho-Chung, and D. L. Longo.
1998.
Involvement of microtubules in the regulation of Bcl-2 phosphorylation and apoptosis through cyclic AMP-dependent protein kinase.
Mol. Cell. Biol.
18:3509-3517[Abstract/Free Full Text].
|
| 27.
|
Wang, L. G.,
X. M. Liu,
W. Kreis, and D. R. Budman.
1999.
The effect of antimicrotubule agents on signal transduction pathways of apoptosis: a review.
Cancer Chemother. Pharmacol.
44:355-361[CrossRef][Medline].
|
| 28.
|
Wang, T.,
D. M. Popp,
H. Wang,
M. Saitoh,
J. G. Mural,
D. C. Henley,
H. Ichijo, and J. Wimalasena.
1999.
Microtubule dysfunction induced by paclitaxel initiates apoptosis through both c-Jun N-terminal kinase (JNK)-dependent and -independent pathways in ovarian cancer cells.
J. Biol. Chem.
274:8208-8216[Abstract/Free Full Text].
|
| 29.
|
Wang, T.,
H. Wang,
H. Ichijo,
G. Paraskevi,
J. S. Foster,
T. Fojo, and J. Wimalasena.
1998.
Microtubule-interfering agents activate c-Jun N-terminal kinase/stress-activated protein kinase through both Ras and apoptosis signal-regulating kinase pathways.
J. Biol. Chem.
273:4928-4936[Abstract/Free Full Text].
|
| 30.
|
Wilson, L., and M. A. Jordan.
1994.
Pharmacological probes of microtubule function, p. 59-83.
In
J. S. Hyams, and C. W. Lloyd (ed.), Microtubules. Wiley-Liss, Inc., New York, N.Y.
|
| 31.
|
Xia, Y.,
C. Makris,
B. Su,
E. Li,
J. Yang,
G. R. Nemerow, and M. Karin.
2000.
MEK kinase 1 is critically required for c-Jun N-terminal kinase activation by proinflammatory stimuli and growth factor-induced cell migration.
Proc. Natl. Acad. Sci. USA
97:5243-5248[Abstract/Free Full Text].
|
| 32.
|
Yamamoto, K.,
H. Ichijo, and S. J. Korsmeyer.
1999.
Bcl-2 is phosphorylated and inactivated by an ASK1/Jun N-terminal protein kinase pathway normally activated at G2/M.
Mol. Cell. Biol.
19:8469-8478[Abstract/Free Full Text].
|
| 33.
|
Yujiri, T.,
G. R. Fanger,
T. P. Garrington,
T. K. Schlesinger,
S. Gibson, and G. Johnson.
1999.
MEK kinase 1 (MEKK1) transduces c-Jun NH2-terminal kinase activation in response to changes in the microtubule cytoskeleton.
J. Biol. Chem.
274:12605-12610[Abstract/Free Full Text].
|
| 34.
|
Yujiri, T.,
S. Sather,
G. R. Fanger, and G. L. Johnson.
1998.
Role of MEKK1 in cell survival and activation of JNK and ERK pathways defined by targeted gene disruption.
Science
282:1911-1914[Abstract/Free Full Text].
|
| 35.
|
Yujiri, T.,
M. Ware,
C. Widmann,
R. Oyer,
D. Russell,
E. Chan,
Y. Zaitsu,
P. Clarke,
K. Tyler,
Y. Oka,
G. R. Fanger,
P. Henson, and G. L. Johnson.
2000.
MEK kinase 1 gene disruption alters cell migration and c-Jun NH2-terminal kinase regulation but does not cause a measurable defect in NF-B activation.
Proc. Natl. Acad. Sci. USA
97:7272-7277[Abstract/Free Full Text].
|
Molecular and Cellular Biology, November 2001, p. 7183-7190, Vol. 21, No. 21
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.21.7183-7190.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
