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Molecular and Cellular Biology, September 2000, p. 6826-6836, Vol. 20, No. 18
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Hsp72-Mediated Suppression of c-Jun N-Terminal
Kinase Is Implicated in Development of Tolerance to
Caspase-Independent Cell Death
Vladimir L.
Gabai,1,2
Julia A.
Yaglom,1
Vladimir
Volloch,3
Anatoli B.
Meriin,1
Thomas
Force,4
Maria
Koutroumanis,5
Bernard
Massie,5
Dick D.
Mosser,5 and
Michael
Y.
Sherman1,*
Boston Biomedical Research Institute,
Watertown,1 Tufts University,
Medford,3 and Massachusetts General
Hospital, Charlestown,4 Massachusetts;
Biotechnology Research Institute, Montreal, Quebec,
Canada5; and Medical Radiology Research
Center, Obninsk, Russia2
Received 28 December 1999/Returned for modification 22 February
2000/Accepted 26 June 2000
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ABSTRACT |
Pretreatment with mild heat shock is known to protect cells from
severe stress (acquired thermotolerance). Here we addressed the
mechanism of this phenomenon by using primary human fibroblasts. Severe
heat shock (45°C, 75 min) of the fibroblasts caused cell death
displaying morphological characteristics of apoptosis; however, it was
caspase independent. This cell death process was accompanied by strong
activation of Akt, extracellular signal-regulated kinase 1 (ERK1) and
ERK2, p38, and c-Jun N-terminal (JNK) kinases. Suppression of Akt or
ERK1 and -2 kinases increased cell thermosensitivity. In contrast,
suppression of stress kinase JNK rendered cells thermoresistant. Development of thermotolerance was not associated with Akt or ERK1 and
-2 regulation, and inhibition of these kinases did not reduce acquired
thermotolerance. On the other hand, acquired tolerance to severe heat
shock was associated with downregulation of JNK. Using an antisense-RNA
approach, we found that accumulation of the heat shock protein Hsp72 is
necessary for JNK downregulation and is critical for thermotolerance.
The capability of naive cells to withstand moderate heat treatment also
appears to be dependent on the accumulation of Hsp72 induced by this
stress. Indeed, exposure to 45°C for 45 min caused only transient JNK
activation and was nonlethal, while prevention of Hsp72 accumulation
prolonged JNK activation and led to massive cell death. We also found
that JNK activation by UV irradiation, interleukin-1, or tumor necrosis factor was suppressed in thermotolerant cells and that Hsp72
accumulation was responsible for this effect. Hsp72-mediated
suppression of JNK is therefore critical for acquired thermotolerance
and may play a role in tolerance to other stresses.
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INTRODUCTION |
Cells exposed to nonlethal elevated
temperatures develop resistance to a subsequent severe heat stress, a
phenomenon called acquired thermotolerance. Thermotolerant cells also
become more resistant to some other stressful treatments, such as
ethanol, UV irradiation, doxorubicin (Adriamycin), or tumor necrosis
factor (TNF) (acquired cross-tolerance) (see references
9 and 12 for review). This
protection has mainly been attributed to members of the Hsp70 family
which are induced by mild heat shock. In fact, expression of
recombinant human heat-inducible Hsp70 (Hsp72) in many cell lines
increased their resistance to stresses (1, 8, 22, 23, 30).
On the other hand, priming of cells with mild heat shock induces the
whole group of heat shock proteins (Hsps) besides Hsp72, including
Hsp104, Hsp90, Hsp27, and Hsp40. Some of these proteins function in
protein protection and refolding in cooperation with Hsp70 family
members (e.g., Hsp40 or Hsp90), while others function independently of
Hsp70 family members (e.g., small Hsps or Hsp104) (see reference
7 for review). Furthermore, in addition to induction of Hsps, mild heat shock activates phosphorylation of Hsp27, which may
be important for thermotolerance (21). Therefore, protective effects of cell preheating may be potentially unrelated to induction of
Hsp72. This possibility is also supported by the fact that much higher
levels of recombinant Hsp72 are usually required for cell protection
than the levels of endogenous Hsp72 achieved by preheating
(33). The first question addressed here is whether Hsp72 is indeed critical for acquired thermotolerance.
It is well known that all stresses, including heat shock, may
potentially kill cells by three distinct modes: reproductive (clonogenic) cell death, apoptosis, or necrosis. Originally the phenomenon of thermotolerance was demonstrated by assessment of colony-forming ability, but later an acquired tolerance to heat-induced apoptosis as well as to necrosis was also reported (10, 23, 26,
32). While little is known about mechanisms of heat-induced necrosis or reproductive death, in heat-induced apoptosis (or programmed cell death) initial damage does not kill cells directly but
turns on specific signaling pathways that lead to the cells' suicide.
Suppression of these pathways prevents the loss of cell viability
despite initial stress-evoked damage. Stress resistance of cells primed
with mild heat shock may be due to downregulation of the signal
transduction pathway that initiates programmed cell death. Indeed,
recombinant Hsp72 has been demonstrated to suppress stress-induced
activation of protein kinases c-Jun N-terminal kinase (JNK) and p38
(8, 30, 43), which were implicated in apoptosis induced by
various stressful treatments (4, 34, 38, 40, 45, 46).
However, the relevance of this regulation to acquired thermotolerance
has not been clarified.
Certain kinases, such as Akt (protein kinase B) and extracellular
signal-regulated kinase (ERK) (p42 and p44 mitogen-activated protein
[MAP] kinases), suppress rather than activate apoptotic signaling,
since inhibition of these kinases decreases cell survival (16, 44,
45). Therefore, if Akt and ERK are involved in protection from
heat-induced apoptosis, their upregulation after mild heat shock
pretreatment could contribute to acquired thermotolerance. Here we
investigated the roles of Akt, ERK, p38, and JNK in heat-induced programmed death and acquired thermotolerance in human fibroblasts.
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MATERIALS AND METHODS |
Cell culture.
IMR90 human lung fibroblasts that underwent 10 to 20 population doublings were grown in minimal essential medium with
20% fetal bovine serum and 2 mM glutamine and were used for all
experiments at 50 to 70% confluence.
Adenovirus-based expression of antisense Hsp72 RNA, Hsp72,
and SEK(K/R).
A recombinant adenovirus vector
expressing Hsp72 antisense RNA was constructed by cloning a dicistronic
transcription unit encoding this RNA and the green fluorescent protein
(GFP) gene, separated by the encephalomyocarditis virus internal
ribosome entry site (25, 31) into an adenovirus vector.
Expression of this transcription unit is controlled by the
tetracycline-regulated transactivator protein tTA (31),
which was expressed from the separate recombinant adenovirus (ADCMVTTA
[24]). Recombinant adenoviruses were generated by
standard techniques as detailed by Jani et al. (15).
Administration of 3 × 107 PFU of each virus per 35-mm
dish was sufficient to infect almost 100% of the cells. This was
confirmed each time by observation under a fluorescent microscope of a
proportion of the cells expressing GFP. A similar adenovirus encoding
sense Hsp72 RNA (ADTR5Hsp72-GFP) was used for expression of Hsp72
(25, 28). As a control, adenovirus expressing GFP under the
regulation of tTA was used. Adenovirus expressing dominant-negative
SEK1 (dnSEK1) (K/R), a kinase-inactive mutant of JNK-activating kinase
SEK1 tagged with M2 FLAG epitope at its amino terminus was also used
(5). Adenoviruses were propagated in 293 cells, and
high-titer stocks were obtained and purified by CsCl2
density gradient centrifugation.
Measurement of JNK activity.
Cells were washed twice with
phosphate-buffered saline on a dish, aspirated, and lysed by thoroughly
scraping with a plastic scraper in 200 µl of lysis buffer per 35-mm
dish (40 mM HEPES [pH 7.5], 50 mM KCl, 1% Triton X-100, 2 mM
dithiothreitol, 1 mM Na3 VO4, 50 mM
-glycerophosphate, 50 mM NaF, 5 mM EDTA, 5 mM EGTA, 1 mM
phenylmethylsulfonyl fluoride, 1 mM benzamidine, and 5 µg each of
leupeptin, pepstatin A, and aprotinin/ml). The lysates were clarified
by centrifugation in a microcentrifuge at 12,000 × g for 5 min. The total protein concentration was measured in the supernatants
by Bio-Rad protein assay reagent, after which they were diluted with
the lysis buffer to achieve equal protein concentrations in all
samples. All procedures were performed at 4°C.
To measure total JNK activity in fibroblasts, 5 µl of extract was
added to a reaction mixture (20-µl final volume), containing final
concentrations of 40 mM HEPES (pH 7.5), 1 mM Na3
VO4, 25 mM -glycerophosphate, 10 mM MgCl2,
20 µM ATP, 15 µCi of [
-32P]ATP, and 40 ng of
recombinant c-Jun. The reaction was allowed to proceed for 30 min at
30°C and was then stopped by adding 10 µl of loading sodium dodecyl
sulfate-polyacrylamide gel electrophoresis buffer. Samples were
separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis
and were transferred to nitrocellulose; membranes were exposed to a
Molecular Imager (Bio-Rad) for quantification. Subsequently, membranes
were immunoblotted with a JNK1 antibody to verify equivalent protein loading.
Another assay for JNK activity in fibroblasts allowed us to measure
separately the activity of two major isoforms, JNK1 and
JNK2 (46 and 54 kDa, respectively), using an antibody specific
to the activated
(phosphorylated) form of JNK (Promega, Madison,
Wis.).
Measurement of Akt, ERK1 and -2, and p38 kinase activities.
Activities of the Akt, ERK1 and -2 (p42 and p44), and p38 kinases were
measured by immunoblotting with corresponding antibodies specific to
phosphorylated (active) kinases either in total cell lysates (Akt and
ERK1 and -2) or in a soluble (supernatant) fraction (p38) which was
obtained as described above for measurement of JNK activity. The
following antibodies (all from New England Biolabs) were used:
phospho-Akt (Thr308), phospho-p42 and -p44 (Thr202 and Tyr204), and
phospho-p38 (Thr180 and Tyr182). Secondary antibodies conjugated with
peroxidase were visualized with enhanced-chemiluminescence substrates
(Amersham, Arlington Heights, Ill.), and resulting films were
quantified by densitometry.
Since phosphorylation of p38 is not suitable for measuring the effect
of the inhibitor SB203580 on p38 activity (
20), another
assay of p38 activity was used. A substrate of p38, MAP
kinase-activated
protein 2 (MAPKAP-2) kinase, was immunoprecipitated
with MAPKAP-2
antibodies for 2 h at 4°C and was washed
three times with the
kinase buffer. MAPKAP-2 kinase activity was
measured using Hsp27
(StressGene) as a substrate (
20).
Cell viability and apoptosis.
Cell viability was measured by
fluorescent microscopy using acridine orange-ethidium bromide staining
as described earlier (30). Cells which were not stained by
ethidium bromide, with normal morphology and noncondensed nuclei, were
considered viable. We counted 300 to 500 cells in each experiment,
which was repeated at least twice. Apoptotic caspase activation was
assayed by immunoblotting of total cell lysates either with antibodies
to caspase 3 (Santa Cruz) or with antibodies (C2 to -10; G. Poirier) to
one of the caspase substrates, poly(ADP-ribose) polymerase (PARP).
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RESULTS |
Acquired thermotolerance in fibroblasts depends on Hsp72
accumulation.
Challenging IMR90 human fibroblasts with severe heat
shock (45°C, 75 min) led to a loss of viability of 80% of the cells. However, pretreatment at 45°C for 30 min followed by 16 h of
recovery dramatically reduced cell death (only about 20% of the cells
died) (Fig. 1C). Although the conditions
used for preheating (45°C, 30 min) may be toxic for other types of
cells (e.g., lymphoid cells), we consider it a mild heat shock for
IMR90 fibroblasts, since it does not affect the viability of these
cells but strongly induces Hsps, including Hsp72 (Fig. 1A).
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FIG. 1.
Prevention of heat-induced Hsp72 accumulation abolishes
acquired thermotolerance in fibroblasts. (A) Expression of Hsp72
antisense RNA prevents heat-induced accumulation of Hsp72 but not that
of other Hsps. IMR90 human fibroblasts were infected with an adenovirus
expressing Hsp72 antisense RNA (AS) and 36 h after infection were
subjected to mild heat shock (45°C, 30 min), followed by recovery for
16 h at 37°C. The levels of Hsp72, Hsc73, and Hsp40 were then
assayed by immunoblotting with corresponding antibodies. C, control
cells; HS, cells incubated with tetracycline (doxycycline, 1 µg/ml)
and exposed to heat shock; AS + HS, cells incubated without
tetracycline and exposed to heat shock. (B) Time course of suppression
of heat-induced Hsp72 accumulation by the Hsp72
antisense-RNA-expressing adenovirus. Fibroblasts were infected with the
Hsp72 antisense-RNA-expressing adenovirus as explained for panel A and
were incubated without tetracycline; at various times after infection,
they were subjected to mild heat shock with recovery as explained for
panel A, and the level of Hsp72 was measured by immunoblotting. The
data shown are the means ± standard deviations of three
replicates. Adv, adenovirus. (C) Prevention of Hsp72 accumulation by
antisense-RNA-expressing adenovirus blocks the acquisition of
thermotolerance. Fibroblasts infected with Hsp72
antisense-RNA-expressing adenovirus and pretreated with mild heat shock
as explained for panel A were exposed to severe heat shock (45°C, 75 min), and cell viability was assayed 24 h later by acridine
orange-ethidium bromide staining. con, control.
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Pretreatment of cells with mild heat shock induces the entire set of
Hsps, activates stress kinases, and may also initiate
some other
adaptive responses. To evaluate the role of Hsp72 in
acquired
thermotolerance in fibroblasts, we blocked accumulation
of this protein
specifically, utilizing a novel approach based
on adenovirus-driven
expression of the Hsp72 antisense RNA. Fibroblasts
were infected with
an adenovirus encoding Hsp72 antisense RNA
along with GFP under the
control of a tetracycline-sensitive transactivator
(see Materials and
Methods for details). In this system GFP serves
as an indicator of
Hsp72 antisense RNA expression. To induce expression
of Hsp72 antisense
RNA, infected cells were incubated without
tetracycline, while as a
control we used infected cells incubated
in the presence of
tetracycline. The virus titer and time of infection
were chosen to
provide expression of GFP (and, correspondingly,
Hsp72) in 90 to 100%
of cells in the absence of tetracycline.
No fluorescence was observed
if cells were incubated in the presence
of tetracycline (data not
shown).
To assess the effect of the Hsp72 antisense RNA on Hsp expression,
cells were infected with the virus for 36 h and were then
subjected to mild heat shock with recovery as described above.
When
expression of Hsp72 and other Hsps was tested by immunoblotting
with
the corresponding antibodies, we found that in cells expressing
antisense RNA, Hsp72 induction was dramatically suppressed, while
neither induction of a distinct Hsp, Hsp40, nor the level of the
heat
shock cognate protein Hsc73 in these cells was changed (Fig.
1A).
Inhibition of the Hsp72 accumulation was dependent on the
time after
viral infection (Fig.
1B) and correlated well with
the increase of GFP
expression as judged by fluorescence microscopy
(not shown). Thus, the
adenoviral expression of Hsp72 antisense
RNA caused strong and specific
suppression of Hsp72 induction.
Inhibition of Hsp72 accumulation in
adenovirus-infected cells
after mild heat shock pretreatment by removal
of tetracycline
almost completely suppressed acquisition of the
tolerance to severe
heat shock (Fig.
1C). In contrast, incubation of
infected cells
in the presence of tetracycline to prevent expression of
Hsp72
antisense RNA did not significantly affect acquisition of
thermotolerance
(Fig.
1C). Therefore, accumulation of Hsp72 is
essential for acquisition
of thermotolerance in
fibroblasts.
Heat-induced cell death in fibroblasts.
To investigate the
mechanism of Hsp72 action in acquired thermotolerance, we first studied
how heat shock kills human fibroblasts. It was reported that under heat
shock, various cells can undergo classical apoptosis manifested by cell
shrinkage, chromatin condensation, activation of caspase 3, and
cleavage of substrates such as PARP, while cells remained impermeable
to supravital dyes (8, 23, 30, 32). The death of
heat-shocked fibroblasts resembled such apoptotic processes
(43). Following heat shock, cells first shrank and then
rounded and detached (Fig. 2A and C).
Furthermore, they remained impermeable
to trypan blue or ethidium bromide while demonstrating chromatin
condensation as judged by staining with acridine orange (Fig. 2B and D)
or Hoechst-33342 (not shown). The morphology of heat-shocked cells was
similar to that of cells treated with the well-known apoptotic inducer
staurosporine (Fig. 2E) or TNF (not shown). On the other hand, such
morphology was clearly different from that of necrotic cells (e.g.,
cells which were heat shocked in serum-free medium): the latter
remained attached to the substratum but became permeable to trypan blue
(Fig. 2F). Therefore, heat shock kills IMR90 human fibroblasts by a
mechanism that morphologically resembles apoptosis.
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FIG. 2.
Characteristics of heat-induced cell death in
fibroblasts. (A to F) Morphological characteristics of dying IMR90
fibroblasts. (A and B) Control cells. (A) Light microscopy; (B)
fluorescent microscopy after staining with acridine orange. (C and D)
Cells subjected to heat shock at 45°C for 75 min and observed 24 h later. (C) Light microscopy; (D) fluorescent microscopy after
staining with acridine orange. (E) Cells were treated with 1 µM
staurosporine for 16 h. (F) Cells were subjected to the same heat
shock as explained for panels C and D but in serum-free medium and were
stained with trypan blue. (G) Apoptosis-associated PARP cleavage (upper
panel) and caspase 3 activation (lower panel) in control cells (C),
cells treated with 1 µM staurosporine (ST), or heat-shocked cells
(45°C, 75 min) (HS). PARP and procaspase 3 cleavages were assayed by
immunoblotting. procas-3, procaspase 3. (H) Effect of caspase inhibitor
zVAD-fmk or Ac-DEVD-CHO on heat-induced or TNF-induced cell death.
Cells were exposed to heat shock (45°C, 75 min) or TNF (10 ng/ml)
plus emetine (10 µg/ml) and incubated either with vehicle (1%
dimethyl sulfoxide) or with zVAD-fmk (100 µM) for 8 h or
Ac-DEVD-CHO (100 µM) for 24 h after the stresses. Cell viability
was assayed by acridine orange-ethidium bromide staining. HS, heat
shock.
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Surprisingly, this heat shock-induced cell death lacked certain other
important characteristics of apoptosis. In fact, neither
the activation
of caspase 3 nor the cleavage of PARP could be
observed in heat-shocked
cells at any time during chromatin condensation
and massive cell
detachment (Fig.
2G). In addition, no effect
on caspase 3 activation or
on PARP cleavage was observed when
we varied the parameters of heat
treatment, i.e., temperature
(from 43 to 46°C), time of heating (from
15 to 90 min), and time
after heat shock (from 12 to 72 h) (not
shown). In contrast, staurosporine-treated
(Fig.
2G) or TNF-treated
(not shown) cells showed both activation
of caspase 3 and PARP
cleavage, indicating that caspase-dependent
apoptosis can be activated
in human fibroblasts. Accordingly,
heat-induced cell death, unlike
TNF-induced apoptosis, was not
suppressed by the caspase 3 inhibitor
Ac-DEVD-CHO or general caspase
inhibitor zVAD-fmk (Fig.
2H). These data
indicate that heat-induced
cell death of fibroblasts, although it
morphologically resembles
apoptosis, is caspase
independent.
In several cell lines, heat shock was reported to activate protein
kinases which are implicated in cell survival and death,
including Akt
kinase (
35), MAP kinases ERK1 and -2 (
44), and
stress kinases JNK and p38 (
8,
30). To address the question
of whether any of these kinases plays a role in the heat-induced,
caspase-independent death of human fibroblasts, we tested their
activation following heat treatment. Cells were heat shocked at
45°C
for different time periods, and activities of the kinases
were assessed
by immunoblotting with antibodies against phosphorylated
(active) forms
of Akt, the ERKs, p38, and JNK. All these kinases
were activated by
heat shock (Fig.
3A through D). We then
tested
whether inhibition of these kinases affects the survival of
heat-shocked
fibroblasts. In these experiments we employed wortmannin
and LY294,002,
inhibitors of the Akt signaling pathway; PD98059, an
inhibitor
of the ERK1 and -2 signaling pathway; and a p38 kinase
inhibitor,
SB203580. Cells preincubated with one of these inhibitors
for
30 min were subjected to heat shock at 45°C for 45 or 75 min,
and
their viability was measured after 24 h of incubation at 37°C
in
the presence of the inhibitors. Inhibition of p38 kinase did
not affect
the thermosensitivity of cells, while inhibition of
Akt kinase or ERKs
dramatically sensitized cells to heat shock
(Fig.
4A and
B).
Indeed, 50 to 80% of cells treated
with wortmannin,
LY294,002, or PD98059 died after heat shock at 45°C
for 45 min,
while the viability of control cells was not compromised by
such
heat treatment (Fig.
4A). It should be noted that any of these
inhibitors alone (without heat shock) did not affect the viability
of
fibroblasts (not shown). Thus, it appears that both Akt kinase
and ERK
facilitate cell survival under heat shock conditions.
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FIG. 3.
Effect of heat shock treatment on the activity of Akt
(A), ERK1 and -2 (B), p38 (C), and JNK (D) kinases in fibroblasts.
IMR90 fibroblasts were exposed to heat shock (45°C) for the indicated
time periods and were then transferred to normal temperature (37°C,
recovery). (A to C) The activity of the Akt, ERK, and p38 kinases was
measured by immunoblotting with antibodies to phosphorylated (active)
kinases. (D) The activity of JNK was assayed by c-Jun phosphorylation
as described in Materials and Methods.
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FIG. 4.
Involvement of Akt, ERK1 and -2 and JNK in heat-induced
death of fibroblasts. (A) Inhibition of Akt and ERK1 and -2 kinases but
not p38 kinase decreases cell viability under moderate heat shock
treatment. IMR90 fibroblasts were pretreated for 30 min with p38 kinase
inhibitor SB203580 (SB) (10 µM), ERK1 and -2 inhibitor PD98059 (PD)
(50 µM), or IP3 kinase inhibitor wortmannin (WM) (100 nM)
or LY294,002 (LY) (50 µM) and were then subjected to heat shock (HS) for 45 or 75 min. Vehicle (0.1% dimethyl
sulfoxide) was added as a control to heat-shocked cells, and cell death
was measured 24 h later as shown in Fig. 1C. con, control. (B)
SB203580 inhibits p38 activity. Fibroblasts were pretreated with
SB203580 as described above and were exposed to heat shock (45°C, 75 min). p38 activity was measured immediately after heat shock by an in
vitro assay of its downstream kinase (MAPKAP-2), using Hsp27 as a
substrate (see Materials and Methods for further details). (C to E)
Inhibition of JNK activity suppresses heat-induced cell death.
Fibroblasts were infected with an adenovirus expressing dnSEK; 72 h after infection, cells were subjected to heat shock (45°C, 75 min)
and expression of dnSEK (C), JNK activity (D), and cell viability (E)
were assayed. Expression of dnSEK was assayed by immunoblotting with
antibodies to SEK1; JNK activity was measured with antibodies to active
(phosphorylated) JNK. Cell viability was assayed as explained for Fig.
1C. The amount of added dnSEK adenovirus shown in panels C and D was 25 relative units (25 × 109 particles per 35-mm plate).
This experiment was reproduced three times. Data shown in panels B to E
represent typical experiments. Adv, adenovirus; rel, relative.
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To test whether JNK is involved in the heat-induced death of
fibroblasts, we inhibited activation of JNK by expression of
dnSEK1.
Cells infected with dnSEK1-expressing adenovirus for 72
h were
challenged with severe heat shock (45°C, 75 min), and activation
of
JNK and cell viability were monitored. Expression of dnSEK1
led to a
dramatic reduction of heat-induced JNK activation (Fig.
4C and D) and
to dose-dependent protection from heat-induced death
almost to the same
degree as achieved by mild heat pretreatment
(cf. Fig.
4E and
1C). As a
control for dnSEK1-expressing adenovirus,
we used GFP-expressing
adenovirus and found that neither JNK activation
nor cell death was
affected by this adenovirus (data not shown).
Thus, despite
heat-induced damage, the inactivation of JNK in
fibroblasts confers
thermoresistance. This finding indicates that
although cell death after
heat shock is caspase independent, it
is apparently a programmed event
which is upregulated by activation
of proapoptotic kinase JNK and is
downregulated by activation
of antiapoptotic kinases ERKs and
Akt.
Hsp72-mediated acquired tolerance is associated with suppression of
stress kinase JNK.
Previous studies indicated that Hsp72 and other
members of the Hsp70 family are involved in regulation of several
protein kinases that are activated by stresses, including
heme-regulated kinase HRI (39),
double-stranded-RNA-activated kinase PKR (27), p38, and JNK
(8, 30, 43). Therefore, since Akt kinase, ERK, and JNK
activities affect the sensitivity of fibroblasts to heat shock (see
above), Hsp72-dependent thermotolerance may be associated with
Hsp72-mediated regulation of any (or all) of these kinases.
To address this problem, fibroblasts that acquired thermotolerance (see
"Acquired thermotolerance in fibroblasts depends on
Hsp72
accumulation" above) were treated with PD98059, wortmannin,
or
LY294,002 and were then exposed to severe heat shock. Treatment
of
cells with the inhibitors did not reduce the survival of preheated
cells challenged with a second severe heat shock (not shown).
Furthermore, pretreatment with mild heat shock did not enhance
activation of either ERKs or Akt by the challenging heat shock
(not
shown). These findings indicate that acquired thermotolerance
is not
associated with upregulation of ERKs or Akt kinases. On
the other hand,
pretreatment with mild heat shock dramatically
suppressed the
activation of JNK by severe heat shock (Fig.
5).
These data suggest that the
protective effect of mild heat shock
pretreatment is mediated by
suppression of JNK and that when JNK
is suppressed, no activities of
Akt or ERKs are required.
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FIG. 5.
Heat-induced JNK activity is suppressed in
thermotolerant fibroblasts. IMR90 fibroblasts were pretreated with mild
heat shock as explained for Fig. 1 and were then exposed to severe heat
shock (45°C, 75 min). JNK activity was measured at the time points
indicated. c-Jun was the substrate.
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Is the effect of heat pretreatment on JNK activation due to
accumulation of Hsp72? To test whether the development of
thermotolerance
and suppression of JNK correlate with induction of
Hsp72, fibroblasts
were preheated at 45°C for 30 min, were returned
to normal temperature,
and after various time intervals were exposed to
a second severe
heat shock (45°C, 75 min). JNK activity was measured
immediately
after the second heat shock, and cell viability was
assessed 24
h later. A slight decline in both JNK activity and
cell death
in response to the second heat shock was already observed at
2
h after the preheating, when no increase in the level of
Hsp72
was yet observed (Fig.
6).
However, further inhibition of JNK
and development of thermotolerance
closely correlated with accumulation
of Hsp72 (Fig.
6), suggesting that
Hsp72-mediated suppression
of JNK may be the basis for acquired
thermotolerance.
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FIG. 6.
Suppression of JNK activation and cell death in
fibroblasts subjected to severe heat shock correlates with Hsp72
accumulation. (A) Suppression of JNK activation in response to severe
heat shock correlates with Hsp72 accumulation after mild heat shock.
Cells were pretreated with mild heat shock (45°C, 30 min), incubated
for different time periods at 37°C, and then subjected to severe heat
shock (45°C, 75 min). JNK activity (upper panel) was measured using
c-Jun as the substrate. JNK activity in nonpreheated cells ( ) after
severe heat shock is also shown. The Hsp72 level (lower panel) was
measured by immunoblotting with antibodies to inducible Hsp72 as
described for Fig. 1A and B. (B) Increase in viability of cells
subjected to severe heat shock correlates with JNK suppression. Cells
were treated as explained for panel A, and their viability was measured
24 h later as explained for Fig. 1C. JNK activity and Hsp72
accumulation were measured as explained for panel A. This experiment
was reproduced three times. Data shown here represent a typical
experiment.
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To test more directly whether suppression of JNK in acquired
thermotolerance is due to accumulation of Hsp72, the antisense-RNA
approach was employed. Fibroblasts infected with the adenovirus
encoding Hsp72 antisense RNA, as described in "Acquired
thermotolerance
in fibroblasts depends on Hsp72 accumulation" above,
were exposed
to heat shock, and JNK activity was measured. As shown
previously,
in control cells, JNK activation after challenging heat
shock
was suppressed by preheating (Fig.
7). By contrast, expression
of Hsp72
antisense RNA completely eliminated the suppression of
JNK activation
by the mild heat shock pretreatment (Fig.
7). Thus,
Hsp72 accumulation
is required for the inhibitory effect of preheating
on activation of
JNK in response to challenging heat shock.
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FIG. 7.
Prevention of heat-induced Hsp72 accumulation eliminates
suppression of JNK in fibroblasts subjected to severe heat shock.
Fibroblasts were infected with adenovirus expressing Hsp72 antisense
RNA, incubated either with (control) or without (+AS) tetracycline.
Then the cells were pretreated with mild heat shock, and after 16 h of recovery, were exposed to severe heat shock as described for Fig.
1C. JNK activity was assayed immediately after severe heat shock by
immunoblotting with antibodies to phosphorylated (active) JNK1 and -2 (upper panel) or JNK1 (lower panel). C, control.
|
|
In line with previously reported data (
28), heat shock did
not upregulate the JNK-activating kinase SEK1, while it inhibited
JNK
dephosphorylation (not shown). Accordingly, pretreatment with
mild heat
shock did not affect the basal level of SEK1 activity,
whereas it
facilitated JNK dephosphorylation after severe heat
shock (not shown).
As discussed previously (
28), the basal SEK1
activity is
critical for activation of JNK upon inhibition of
a phosphatase in
heat-shocked cells, which explains the inhibitory
effect of dnSEK1
expression.
We also checked whether Hsp72 overexpression alone is sufficient to
suppress heat shock-induced JNK activation and cell death.
To express
Hsp72 at high levels, we used an adenovirus construct
encoding sense
Hsp72 RNA in a dicistronic transcription unit together
with GFP.
Incubation of adenovirus-infected cells in the absence
(but not in the
presence) of tetracycline led to GFP fluorescence
in 80 to 100% of
cells (not shown) and caused a marked induction
of Hsp72 (Fig.
8C). This treatment led to strong
suppression of
heat-induced JNK activation and cell death (Fig.
8A, B,
and E).
As stated earlier, expression of GFP alone had no effect on JNK
activity and cell viability under these conditions. Therefore,
Hsp72
accumulation is necessary and sufficient for the inhibitory
effect of
preheating on JNK activation and cell death in response
to severe heat
shock. It should be noted that the level of recombinant
Hsp72 necessary
for suppression of JNK and cell protection was
higher than the level
induced by mild heat shock.
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|
FIG. 8.
Expression of Hsp72 at high levels suppresses
heat-induced JNK activation and cell death. Fibroblasts were infected
with recombinant adenovirus expressing Hsp72 and were incubated for
36 h either with (Mock) or without (+Hsp72) tetracycline. Then the
cells were exposed to heat shock (HS) (45°C, 75 min), and JNK
activity was assayed immediately afterward. Viability was assayed
24 h later. (A to D) C, control. (A) JNK activity as assayed using
c-Jun as the substrate; (B) JNK activity as assayed by immunoblotting
with antibodies to phosphorylated (active) JNK1 and -2; (C) Hsp72
expression as assayed by immunoblotting; (D) JNK1 expression as assayed
by immunoblotting; (E) Cell viability as assayed by acridine
orange-ethidium bromide staining. con, control.
|
|
Accumulation of Hsp72 is necessary for intrinsic thermoresistance
and inactivation of JNK.
Adenovirus expressing Hsp72 antisense RNA
in fibroblasts, which is nontoxic at normal temperatures, unexpectedly
caused toxicity under heat shock. Indeed, heating at 45°C for only 30 min caused the death of 25% of the cells (Fig.
9A). Furthermore, exposure to 45°C for
45 min, which is nontoxic in control cells, caused loss of viability in
almost 100% of the Hsp72 antisense-RNA-expressing cells; i.e., it was
more toxic than heating control cells for 75 min (Fig. 9A). The
thermosensitizing effect of Hsp72 antisense RNA is not due to
adenoviral infection itself, since incubation of infected cells with
tetracycline to block RNA expression abolished this effect (Fig. 9A).
Therefore, Hsp72 not only is essential for development of
thermotolerance (Fig. 1) but also is involved in intrinsic cellular
thermoresistance. This finding indicates that heat stress
simultaneously triggers synthesis of Hsps and activates the cell death
program and that Hsp72, when accumulated, blocks this program.
Consequently, failure to induce Hsp72 leads to cell death.
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|
FIG. 9.
Prevention of heat shock-induced Hsp72 accumulation in
fibroblasts delays JNK inactivation after moderate heat shock and
decreases cell viability. (A) Expression of Hsp72 antisense RNA
decreases the thermoresistance of fibroblasts. Fibroblasts infected
with adenovirus expressing Hsp72 antisense RNA and incubated in the
presence or absence of tetracycline as described for Fig. 1A were
subjected to heat shock (45°C) for various time periods. Cell
viability was assayed 24 h later as described for Fig. 1C. (B and
C) Expression of Hsp72 antisense RNA delays JNK inactivation after
moderate heat shock. Fibroblasts were infected with adenovirus as
explained for panel A. JNK inactivation in control (with tetracycline)
or in Hsp72 antisense (AS)-RNA-expressing fibroblasts (without
tetracycline) after heat shock (45°C, 45 min) was measured at the
indicated time points using c-Jun as the substrate. C, control. (C)
Quantification of JNK deactivation and Hsp72 accumulation after the
same heat shock in control (open symbols) or in Hsp72
antisense-RNA-expressing cells (filled symbols) is shown. The Hsp72
level was assayed as described for Fig. 1A and B.
|
|
How can Hsp72, which accumulates in cells only several hours after heat
treatment (Fig.
6), turn off the death program initiated
by this
treatment? It has recently been demonstrated that heat-induced
death of
Rat-1 cells depends on the duration of JNK activation
rather than its
initial heat-induced activity (
41). On the other
hand,
expression of recombinant Hsp72 accelerates JNK inactivation,
thus
rescuing cells from apoptosis (
41,
42). It was suggested
that Hsp72 accumulated after nontoxic heat shock is responsible
for the
decline of JNK activity. To test this suggestion, we compared
the
dynamics of JNK activity after heat shock in control and Hsp72
antisense-RNA-expressing cells. In control cells exposed to 45°C
for
45 min, JNK was rapidly activated and then the activity declined,
so
that after 6 h of recovery, JNK activity fell almost to the
background level (Fig.
9B and C). However, in Hsp72
antisense-RNA-expressing
cells, JNK inactivation was drastically slowed
down, so that even
after 10 h the level of JNK activity was still
about 80% of the
maximum (Fig.
9C). In these cells, the death program
was activated,
and they died within 24 h (Fig.
9A). Therefore, in
cells exposed
to moderate heat shock, Hsp72-mediated JNK inactivation
is apparently
required for
survival.
Hsp72 is required for suppression of JNK activation in preheated
cells in response to various stresses.
Can preheating of cells
suppress JNK activation induced by various stresses besides heat shock,
and what is the role of Hsp72 in this suppression? As JNK-activating
stimuli, we chose interleukin-1 (IL-1), UV-C, and TNF. Preheating of
fibroblasts at 45°C for 30 min, which blocked JNK activation by
severe heat shock (Fig. 5), did not significantly suppress JNK
activation by these stimuli (not shown). However, stronger heat shock
pretreatment (45°C for 45 min), which led to a higher level of Hsp72
(not shown), caused marked suppression of JNK activation by all these
stimuli (Fig. 10). To test whether
suppression of JNK activation under these conditions depends on
accumulation of Hsp72, cells were infected with the virus expressing
Hsp72 antisense RNA. As described above, when induction of Hsp72 was
inhibited, heat shock at 45°C for 45 min became toxic due to
sustained JNK activation (Fig. 9A). This toxicity, however, was
manifested only after 24 h of recovery, and at 12 to 16 h of
recovery, most cells did not demonstrate any signs of death (i.e.,
chromatin condensation and detachment) (not shown). Thus, at 16 h
after the heat shock treatment, control cells and cells expressing
Hsp72 antisense RNA were exposed to UV-C radiation, TNF, or IL-1.
Prevention of Hsp72 induction by antisense RNA increased the basal
level of JNK activity due to inhibition of JNK inactivation and
completely abolished the inhibitory effects of preheating on JNK
activation by these stimuli (Fig. 10). Therefore, accumulation of Hsp72
in preheated cells plays a critical role in suppression of JNK
activation not only by heat shock but also by other stimuli.
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FIG. 10.
Heat shock (HS)-induced suppression of JNK under
diverse stresses depends on Hsp72 accumulation. Fibroblasts were
subjected to heat shock (45°C, 45 min) followed by recovery for
16 h and were then exposed to IL-1 (20 ng/ml) (A and D), UV-C
irradiation (400 J/M2) (B and E), or TNF (10 ng/ml) plus
cycloheximide (CHX) (10 µg/ml) (C and F). JNK activity was assayed
either by using c-Jun as the substrate (A, B, D, and E) or by
immunoblotting with antibodies to phosphorylated (active) JNK (C and
F). "AS + heat shock" shows JNK activity after heat shock in
cells infected with Hsp72 antisense-RNA-expressing adenovirus as
described for Fig. 1A. In panels D to F, densitometric data of the
experiments shown in panels A to C are presented.
|
|
| |
DISCUSSION |
Priming of cells with mild heat shock leads to thermotolerance
(3, 10, 23, 32, 43); however, the role of Hsp72 in this
process has not been addressed specifically. Indeed, mild heat shock
can induce a variety of Hsps besides Hsp72 (e.g., Hsp40, Hsp27, and
Hsp90) through heat shock factor activation, as well as some proteins
whose expression depends on activation of transcriptional factors, such
as AP-1 (6; see also reference 17
for review). In addition, heat pretreatment activates a number of
posttranscriptional events (e.g., heat-induced Hsp27 phosphorylation
[21]) which may contribute to heat tolerance.
Therefore, to evaluate the role of Hsp72 in thermotolerance, it is
necessary to specifically inhibit Hsp72 accumulation without affecting
the expression of other proteins.
Inspired by previous publications, we first approached this goal by
using 15- to 24-mer synthetic Hsp72 antisense oligonucleotides, including oligonucleotides complementary to the 5' translated region of
Hsp72. However, the effects of these oligonucleotides were quite
nonspecific (i.e., similar to that of sense or random-sequence oligonucleotides) (unpublished data). Therefore, in this study we
applied a novel approach: expression of the full antisense Hsp72 RNA by
a recombinant adenovirus under the control of a tetracycline-regulated promoter. We found that this treatment was very effective and specific.
Indeed, expression of Hsp72 antisense RNA markedly (by about 75%)
reduced heat-induced accumulation of Hsp72 without any effect on the
closely related Hsc73 or on Hsp40 (Fig. 1A). Thus, an adenovirus
expressing Hsp72 antisense RNA appears to be a very helpful tool for
elucidating the role of this protein in various heat-inducible
processes. Using this approach, we demonstrated that Hsp72 accumulation
is crucial for acquired thermotolerance (Fig. 1C). In other words, the
whole scope of other events triggered by mild heat shock was
insufficient to significantly protect cells. As a model for these
experiments, we used an IMR90 primary human fibroblast culture at early
passages (10 to 20), since it is more physiologically relevant than
stable cultures of immortalized cells. In later passages of fibroblasts
(30 to 40), antisense-RNA-expressing adenovirus was also effective but
to a lesser extent (unpublished data).
An unexpected finding of this work is that heat shock induces an
unusual caspase-independent type of cell death in the primary fibroblasts which is distinct from classical apoptosis. On the other
hand, this death is a regulated process, since it requires activation
of JNK and can be suppressed by the ERKs and Akt kinases (Fig. 3 and
4). Therefore, it appears to be a programmed cell death, which may be
similar to a caspase-independent apoptosis (see reference
2 for review), and morphologically this kind of
death is very different from necrosis (Fig. 2F). Accordingly, Hsp72
appears to regulate various types of cell death that are activated by JNK.
Another problem addressed in this study is the mechanism of acquired
thermotolerance. Earlier works suggested that this mechanism may be
based on the Hsp72-mediated suppression of stress kinase JNK (8,
30, 43). In the present study we obtained evidence in favor of
this mechanism. This evidence is based on the following observations.
(i) The time course of acquisition of thermotolerance correlated with
that of Hsp72 accumulation and JNK suppression (Fig. 6). (ii)
Prevention of heat-induced Hsp72 accumulation eliminated the
suppression of JNK activity and development of thermotolerance (Fig. 1
and 7). (iii) Suppression of heat-induced JNK activity by expression of
dnSEK1, an upstream component of the JNK signaling pathway, markedly
reduced heat-induced cell death (Fig. 4). Therefore, Hsp72-mediated
suppression of JNK appears to be an important component of acquired
thermotolerance (Fig. 11). On the other
hand, pretreatment of cells with mild heat shock did not upregulate
either ERKs or Akt in response to the challenging heat shock.
Therefore, the development of thermotolerance is unrelated to
upregulation of these kinases.
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|
FIG. 11.
Participation of Hsp72 and heat shock-activated kinases
in caspase-independent cell death of fibroblasts. Heat shock causes
rapid activation of JNK, ERK, Akt, and p38 kinases and slow induction
of Hsp72. JNK activation leads to cell death, while ERK and Akt
activation enhances survival. Hsp72 can prevent cell death via
suppression of JNK but not through activation of ERK or Akt. Prevention
of Hsp72 accumulation by antisense-RNA expression (AS RNA) eliminates
the inhibitory effect of mild heat shock on JNK activity and abolishes
thermotolerance. PD, PD98059; WM, wortmannin; SB, SB203580.
|
|
It should be noted that acquired thermotolerance may partly depend on
heat-induced (activated) factors besides Hsp72. Indeed, in fibroblasts
a slight decline in both JNK activation and death in response to a
challenging heat shock was observed at 2 h after the preheating,
when no increase in the Hsp72 level could be detected yet (Fig. 6A and
B). Therefore, this initial (though rather minor) JNK suppression and
thermotolerance acquisition are independent of Hsp72 accumulation.
Interestingly, this Hsp72-independent protection in fibroblasts appears
to be also associated with JNK suppression (Fig. 6A and B). This
protection may be related to rapid induction of a JNK phosphatase
(e.g., mitogen-kinase phosphatase 1) whose expression is also activated
by heat shock (18, 19), or it could also be independent of
the synthesis of novel proteins (21). On the other hand, it
is clear that the major and limiting factor in JNK regulation is Hsp72,
since its overexpression is sufficient to suppress JNK, while specific
inhibition of Hsp72 induction prevents JNK suppression (Fig. 11).
In addition to Hsp72, other heat-induced proteins may also participate
in suppression of JNK. Indeed, to block JNK activation by expression of
Hsp72 alone, much higher levels of Hsp72 are needed than that induced
by mild heat shock (Fig. 8) (8, 43). One of the heat-induced
proteins implicated in JNK suppression in cooperation with Hsp72 may be
Hsp40, a well-known cochaperone which increases the binding of Hsp72 to
substrates (11, 29). Other Hsp72 cofactors, like BAG-1 or
Hip, as well as Hsp90, may also play a role in this regulation. In
fact, BAG-1 was reported to function in suppression of apoptosis
(37). It is possible that its prosurvival activity is
mediated by the interaction of BAG-1 with Hsp72 and consequently with JNK.
A rather unexpected observation made in this study is that the
intrinsic resistance of cells to moderate heat shock is dependent on
the accumulation of Hsp72. Indeed, exposure of fibroblasts to 45°C
for 45 min, which was not toxic in control cells, evoked a massive
death of cells expressing Hsp72 antisense RNA (Fig. 9A). This
phenomenon is probably related to the previous observation that
heat-induced apoptosis requires prolonged JNK activation, while
transient although strong JNK activation is insufficient to induce cell
death (41). Accordingly, in control fibroblasts which were
able to accumulate Hsp72, JNK activity after heat shock returned to the
basal level within 6 h. In contrast, in the cells where Hsp72
accumulation was blocked, JNK activity remained elevated for a much
longer time period (Fig. 9C). Therefore, accumulated Hsp72 may
participate in the decline of JNK activity after heat stress, thus
preventing induction of cell death.
Apparently, there is a fine balance in a cell between Hsp72 synthesis
and the triggering of death after heat shock (Fig. 11). It appears that
during the first hours after heat shock, cells try to synthesize Hsp72
in order to repair damaged molecules and survive. If they fail to
synthesize enough Hsp72 during this initial period (e.g., in the
presence of Hsp72 antisense virus), the death program prevails.
Interference with the death program during this time (e.g., by
suppression of JNK via dnSEK1-expressing adenovirus) leads to cell
survival, although the cells' reparation capability is likely to
remain unchanged (Fig. 11).
It is known that both pretreatment with mild heat shock and expression
of recombinant Hsp72 can protect cells from apoptosis caused by a
variety of stresses, including UV irradiation (36) and TNF
(3, 13, 14). On the other hand, JNK was shown to be
essential for initiation of apoptosis by these stimuli, at least in
certain cell lines (4, 38, 40, 46). Therefore, we have
previously proposed that mild heat shock or expression of Hsp72
suppresses activation of JNK by these agents, thus preventing apoptosis
(9). In this work we tested an important prediction of this
proposal and found that heat shock pretreatment did suppress JNK
activation by such diverse stresses as UV irradiation and TNF and that
accumulation of Hsp72 is necessary for this regulation (Fig. 10). These
data suggest that Hsp72-mediated JNK suppression may play an important
role not only in acquired thermotolerance but also in tolerance of
various other stressful stimuli.
| |
ACKNOWLEDGMENTS |
This study was supported by an RO1 grant from the NIH to M.Y.S.
and by a BBRI scholarship to J.A.Y.
We thank Sophia Ritz-Volloch for help with experiments.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Boston
Biomedical Research Institute, 64 Grove St., Watertown, MA 02472. Phone: (617) 658-7776. Fax: (617) 972-1761. E-mail:
sherman{at}bbri.org.
| |
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Molecular and Cellular Biology, September 2000, p. 6826-6836, Vol. 20, No. 18
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
