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Molecular and Cellular Biology, September 1998, p. 5091-5098, Vol. 18, No. 9
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Heat Shock Response and Protein Degradation:
Regulation of HSF2 by the Ubiquitin-Proteasome Pathway
Anu
Mathew,
Sameer K.
Mathur, and
Richard I.
Morimoto*
Department of Biochemistry, Molecular
Biology, and Cell Biology, Rice Institute for Biomedical Research,
Northwestern University, Evanston, Illinois 60208
Received 19 March 1998/Returned for modification 9 June
1998/Accepted 15 June 1998
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ABSTRACT |
Mammalian cells coexpress a family of heat shock factors (HSFs)
whose activities are regulated by diverse stress conditions to
coordinate the inducible expression of heat shock genes. Distinct from
HSF1, which is expressed ubiquitously and activated by heat shock and
other stresses that result in the appearance of nonnative proteins, the
stress signal for HSF2 has not been identified. HSF2 activity has been
associated with development and differentiation, and the activation
properties of HSF2 have been characterized in hemin-treated human K562
erythroleukemia cells. Here, we demonstrate that a stress signal for
HSF2 activation occurs when the ubiquitin-proteasome pathway is
inhibited. HSF2 DNA-binding activity is induced upon exposure of
mammalian cells to the proteasome inhibitors hemin, MG132, and
lactacystin, and in the mouse ts85 cell line, which carries a
temperature sensitivity mutation in the ubiquitin-activating enzyme
(E1) upon shift to the nonpermissive temperature. HSF2 is labile, and
its activation requires both continued protein synthesis and reduced
degradation. The downstream effect of HSF2 activation by proteasome
inhibitors is the induction of the same set of heat shock genes that
are induced during heat shock by HSF1, thus revealing that HSF2 affords
the cell with a novel heat shock gene-regulatory mechanism to respond
to changes in the protein-degradative machinery.
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INTRODUCTION |
The cellular response to stresses
such as heat shock is tightly controlled at the level of transcription,
and in larger eukaryotes it is mediated by a family of heat shock
transcription factors (HSFs) corresponding to HSF1 through HSF4
(37, 38, 65), which recognize and bind to heat shock
elements (HSEs) present in the promoter regions of heat shock genes
(11). The expression of multiple HSF family members in
larger eukaryotes endows the cell with a mechanism to sense and respond
to diverse forms of stress. HSF1 and HSF3 are activated following
exposure to traditional forms of environmental and physiological stress
such as heat shock and chemical stress (37, 38, 41, 65). In
avian cells expressing HSF1 but in which the HSF3 gene is deleted, the
heat shock response is strongly diminished, which reveals a new level
of regulatory interaction among members of the HSF family
(57). The suggestion that HSFs may exhibit complex
interactions with other transcription factors is further demonstrated
by the observation that HSF3 expressed in avian cells can be activated
in the absence of stress by direct protein-protein interaction with the
DNA binding domain of the c-Myb proto-oncogene (27).
Another member of the HSF family, HSF2, is 40% related in sequence to
HSF1 and HSF3, with the regions of highest sequence conservation
corresponding to the DNA-binding and heptad repeat regions. However,
unlike HSF1 and HSF3, HSF2 is not activated in response to heat shock
and most other forms of cellular stress (37, 38, 65). HSF2
has been described as having properties of a development- and
differentiation-associated transcription factor, in part due to
observations of HSF2 activation during murine embryogenesis and
spermatogenesis (36, 45, 48). The regulatory and biochemical
properties of HSF2 have been characterized during hemin-induced
differentiation of K562 human erythroleukemia cells; under these
conditions, HSF2 is activated from an inert dimer to a DNA binding,
transcriptionally active trimer (55, 56, 58). Despite the
distinctions in activation signals for HSF1 and HSF2, we have observed
that a similar profile of heat shock genes is transcriptionally induced
when either is activated (55, 56). It has however, been
unclear whether HSF1 and HSF2 display redundancy in target gene
expression or whether there are differences in the patterns of genes
expressed. Random oligonucleotide selection experiments using
recombinant HSF1 and HSF2 have shown that both factors bind to the same
5'-NGAAN-3' motif of the HSE, although they bind preferentially to
slightly different configurations of the HSE sequence (29).
These experiments, in conjunction with in vivo and in vitro analyses of
HSE promoter occupancy, also revealed that HSF2, unlike HSF1, does not
bind to DNA in a cooperative manner (29, 30, 55, 56). Such
studies have raised the possibility that HSF2 may have target genes
distinct from those of HSF1, as well as differing specificities for
common target genes. These speculations have been corroborated by
various recent observations. Analyses of the transcriptional properties of human HSF1 and HSF2 in yeast have identified differences in which
target stress genes are induced preferentially (35).
Furthermore, examination of transcripts differentially expressed under
conditions of HSF1 and HSF2 activation in K562 cells facilitated
identification of the thioredoxin gene as an HSF2-specific target,
although the presence of HSEs in the thioredoxin gene promoter has yet
to be confirmed (33).
HSF1 activation occurs as a general response to conditions such as heat
shock, oxidative stress, and exposure to amino acid analogs, which lead
to the appearance of nonnative proteins (37, 38, 48a, 52a,
65). Because heat shock also causes an inhibition of protein
synthesis and in doing so prevents the appearance of potentially
misfolded nascent polypeptides, it has been considered that the role of
HSF1 is to respond to the appearance of potentially damaging proteins
by enhancing the expression of heat shock proteins. The fate of
nonnative proteins in the environment of the stressed cell is therefore
dependent upon chaperone activity; chaperones may maintain intermediate
folded states, refold the proteins to the native state, or target them
for degradation (19, 39). In contrast to our state of
understanding of HSF1, HSF2 has remained a puzzle. The only
well-established regulator of HSF2 activity is hemin, which, although
effective for K562 erythroleukemia cells, was ineffective as an inducer
of other vertebrate cells (58). Hemin is an iron-containing
protein with potential for oxidative damage; however, it is unlikely
that its HSF-activating properties involve oxidative stress, as we and
others have shown that conditions known to induce oxidative stress
activate HSF1 and not HSF2 (26, 28, 34, 47). Hemin also has
the distinctive characteristic of affecting the function of the
ubiquitin-proteasome pathway in eukaryotes (9, 20, 63). In
this study, we show that down-regulation of the ubiquitin-proteasome
pathway by inhibitors such as hemin, MG132, or lactacystin activates
HSF2 DNA-binding activity in a cell type-independent mechanism.
Consistent with this, HSF2 is a labile protein which accumulates upon
arrest of proteasome activity. Thus, HSF2 is regulated by signaling
mechanisms distinct from those for HSF1 activation.
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MATERIALS AND METHODS |
Preparation of cell extracts and gel mobility shift assays.
The human tissue culture cell lines K562 (grown in RPMI 1640 supplemented with 10% fetal calf serum), HeLaS3 (grown in Joklik's medium with 5% calf serum), and HepG2 (grown in Eagle's minimal essential medium with 10% fetal calf serum, sodium pyruvate, and nonessential amino acids), and mouse embryo fibroblasts (MEF; a gift of
I. J. Benjamin, Southwestern Medical School) (grown in Dulbecco's
modified Eagle's medium plus 10% fetal calf serum, nonessential amino
acids, and 0.5 µM 
-mercaptoethanol), were treated with 20 µM
bovine hemin (Aldrich), 10 µM cycloheximide (Sigma), 10 µM MG132
(Peptides International), or 10 µM lactacystin (E. J. Corey,
Harvard University) as indicated. Cells were alternatively heat shocked
at 42°C and allowed to recover for the lengths of time indicated. The
ts85 cells (a gift of M. Rechsteiner, University of Utah School of
Medicine) were maintained at 30°C (10% CO2) in McCoy's
modified 5A medium plus 10% fetal calf serum or were shifted to
39.5°C for the lengths of time indicated. The cells were harvested
for the preparation of whole-cell extracts and analyzed for HSF
DNA-binding activity in the gel mobility shift assay by using labeled
HSE-containing oligonucleotides, and specific antibodies to HSF2 or
HSF1 as described previously (40, 47), to establish the
composition of the HSE-binding activities obtained.
Immunological analyses.
For immunoblot analyses, cell
extracts (10-µg protein samples) were resolved by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) (8 or 10%
polyacrylamide) and transferred to nitrocellulose, and HSF2 protein was
detected by using polyclonal sera raised against murine HSF2 (1:10,000
dilution of serum), as described previously (47). Other
antibodies used were the murine HSF1-specific polyclonal sera
(47) (1:2,000 dilution of serum), the Hsp70-specific
monoclonal antibody 4G4 (40a) (1:10,000 dilution of ascites
fluid) or 3A3 (2) (1:20,000 dilution of ascites fluid), and
polyclonal sera raised against Hdj-1 (16a) (1:2,500 dilution
of serum) and ubiquitin (a gift of A. Ciechanover, Technion-Israel
Institute of Technology) (1:5,000 dilution of serum). Immunoreactivity
was detected by ECL (Amersham).
Cell extracts (100 to 150 µg of protein) were alternatively used for
immunoprecipitation analyses, incubated either with 0.4 µg of ascites
protein containing monoclonal anti-HSF2 antibody (3E2) (6a)
and 20 µg of rabbit anti-rat linker antibody (Jackson Laboratories)
or with linker antibody alone for 2 h. Following the addition of
protein A-Sepharose beads (Pharmacia), the samples were incubated for
an additional 1 to 2 h at 4°C. The beads were washed with
radioimmunoprecipitation assay buffer (10 mM Tris [pH 8.0], 150 mM
NaCl, 1% Triton X-100, 1% sodium deoxycholate, 1% SDS) and boiled in
2× Laemmli buffer, and the eluates were resolved by SDS-8% PAGE.
One- and two-dimensional protein analyses of
35S-labeled extracts.
K562 cells were pulse-labeled
with Tran35S label (ICN), 200 µCi/ml, in Met- and
Cys-deficient RPMI or Dulbecco's modified Eagle's medium (ICN) for 15 min following treatment with MG132 for 0, 2, or 6 h and were used
for immunoprecipitation assays to detect HSF2. The immunoprecipitates
were resolved on an SDS-8% PAGE gel and analyzed by fluorography.
For analyses of chaperone expression, K562 cells were pulse-labeled
with Tran
35S label (ICN), 50 µCi/ml, in Met- and
Cys-deficient RPMI medium
for 30 min following their respective
treatments with proteasome
inhibitors or heat shock. However, the HS
sample was additionally
allowed to recover for 30 min at 37°C prior
to the
35S labeling. Cell extracts were prepared as
described above, and
10 µg of each sample was resolved by SDS-10%
PAGE. The samples
were transferred onto nitrocellulose and visualized
on a PhosphorImager
(Molecular Dynamics). One hundred micrograms of
35S-labeled extracts were subjected to two-dimensional
protein analysis
using ampholines (pH 3 to 10) for isoelectric focusing
and SDS-10%
PAGE for the second dimension (
42). The
proteins were then visualized
on the PhosphorImager.
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RESULTS |
HSF2 activation by inhibition of proteasome activity.
Incubation of human K562 cells with a proteasome inhibitor
hemin, the
peptide aldehyde MG132 (43, 46), or the
Streptomyces metabolite lactacystin
(10)resulted in the appearance of HSF DNA-binding activity
detected by the gel mobility shift assay (Fig.
1A, lanes 1 to 4). To examine whether
this corresponded to either of the predominant HSE-binding activities
expressed in mammalian cells, HSF1 or HSF2, we used specific polyclonal antisera for antibody supershift assays (47, 56). As shown in Fig. 1B (lanes 1 to 6), the DNA-binding activity induced by the
proteasome inhibitors hemin and MG132 corresponds primarily to HSF2, as
detected by the appearance of slower-migrating HSF2 antibody-containing
ternary complexes in native-gel electrophoresis. However, unlike the
cell type-specific effects of hemin, which induces HSF2 DNA-binding
activity only in K562 cells, the HSF2-activating effects of MG132 or
lactacystin were observed in a large number of vertebrate (primate,
canine, and rodent) cell lines, revealing that inhibition of the
ubiquitin-proteasome pathway is a common activator of HSF2 (Fig. 1A,
lanes 5 to 11, and data not shown).
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FIG. 1.
Activation of HSF2 by treatment of cells with specific
proteasome inhibitors. (A) Gel mobility shift assays to analyze
formation of HSF-HSE complexes using whole-cell extracts prepared from
untreated K562, HeLaS3, and HepG2 cells and MEF (lanes 1, 5, 8, and 10, respectively), from K562 cells treated with hemin for 12 h (lane
2) or with MG132 or lactacystin (Lac) for 2 h (lanes 3 and 4, respectively), from HeLaS3 cells treated with MG132 or lactacystin for
6 h (lanes 6 and 7, respectively), from HepG2 cells treated with
MG132 for 2 h (lane 9), and from MEF treated with MG132 for 2 h (lane 11). (B) Identification of the DNA-binding activity as
primarily HSF2 by antibody supershift assays. Extracts from hemin- and
MG132-treated K562 cells (lanes 1 to 3 and 4 to 6, respectively) were
incubated either with or without a 1:50 dilution of specific HSF2 or
HSF1 antisera, as indicated, prior to the gel mobility shift assay.
Similarly, extracts from MEF heat shocked at 42°C for 1 h (lanes
7 to 9) or treated with MG132 for 6 h (lanes 10 to 13) were
incubated in the presence or absence of either the antiserum specific
to HSF1, the antiserum specific to HSF2, or both. The HSF DNA-binding
activities are indicated by arrows. NS, nonspecific binding.
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Inhibition of the ubiquitin-proteasome pathway resulted in activation
of HSF2 DNA-binding activity; however, we also noticed
that variable
amounts of HSF DNA-binding activity remained after
the addition of
anti-HSF2 antibodies (Fig.
1B, lanes 5 and 11).
One interpretation of
this observation is that other HSF DNA-binding
activities, presumably
HSF1, are also activated in a cell type-dependent
manner. One example
is in MEF, where MG132 treatment led to the
complete coactivation of
both HSF2 and HSF1 (Fig.
1B, lanes 11
to 13), whereas only HSF1 was
activated upon heat shock (Fig.
1B, lanes 7 to 9).
HSF2 is activated in a cell line expressing a conditional mutation
in the ubiquitination pathway.
One interpretation of these results
is that some property of HSF2 is regulated by the activity of the
proteasome. Therefore, as a complement to the use of proteasome
inhibitors, we examined the properties of HSF2 in the mouse cell line
ts85, which carries a temperature sensitivity mutation in the
ubiquitin-activating enzyme E1 that results in reduced levels of
ubiquitination at the restrictive temperature (12). Under
conditions of normal cell growth (30°C), HSF DNA-binding activity was
not detected; however, at the nonpermissive temperature (39.5°C),
HSF2 DNA-binding activity was induced (Fig.
2A). As HSF2 DNA-binding activity was not
induced at 39.5°C in the parental cell line (data not shown), we
conclude that deregulation of proteolytic activity by inhibition at a
specific step in the ubiquitination pathway leads to activation of HSF2
DNA-binding activity with negligible effects on HSF1 activity (Fig.
2B). Taken together, the results presented in Fig. 1 and 2, obtained by
using either chemical inhibitors of the ubiquitin-proteasome pathway or
an E1 enzyme conditional mutant, reveal that the activity of HSF2 is
closely linked to changes in the activity of the ubiquitin-proteasome pathway. Thus, conditions and reagents which inhibit the activity of
the proteasome pathway serve to induce HSF2 activity in a cell type-independent manner.
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FIG. 2.
Inhibition of efficient ubiquitination activates HSF2.
(A) Gel shift analysis of ts85 cells maintained at control (30°C)
(lane 1) and nonpermissive (39.5°C) (lanes 2 to 4) temperatures for
the lengths of time shown. (B) Antibody supershift analyses of the
sample at 39.5°C for 6 h were performed by incubation of
extracts in the absence (lane 1) or presence of antiserum specific for
HSF2 (lane 2) or HSF1 (lane 3).
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HSF2 is a labile protein which accumulates during proteasome
inhibition.
Activation of HSF2 during down-regulation of the
ubiquitin-proteasome degradative system suggests that either HSF2 or a
component in the pathway of HSF2 activation is labile. Consequently,
the accumulation either of HSF2 or of another protein leads to HSF2 activation. Exposure of MEF to MG132 resulted in increased levels of
the 
and isoforms of HSF2 (15, 18), as detected by
immunoblot analysis using anti-HSF2 antibodies, and a parallel increase
in HSF2 DNA-binding activity (Fig. 3A,
top and middle panels). By comparison, the levels of HSF1 protein in
MG132-treated MEF were unaffected (Fig. 3A, bottom panel), although the
electrophoretic mobility of HSF1 from MG132-treated cells by SDS-PAGE
analysis corresponded to the stress-inducible phosphorylated state of
the factor. HSF2 levels also increased in MG132- or hemin-treated K562
cells (Fig. 3C and D and Fig. 4A) and in ts85 cells at the restrictive
temperature, corresponding to the appearance of HSF2 DNA-binding
activity (Fig. 3B, lanes 1 to 3). Comparison of HSF2 levels in five
different mammalian cell lines treated with MG132 revealed increases
ranging from 2-fold in K562 to 35-fold in MEF.
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FIG. 3.
Coordinate changes in HSF2 DNA-binding activity and
protein levels, determined by gel mobility shift (upper panels) and
immunoblot (lower panels) assays of whole-cell extracts from MEF
treated with MG132 for up to 6 h (A), ts85 cells incubated at the
nonpermissive temperature for up to 4 h in the presence (lanes 4 and 5) or absence (lanes 2 and 3) of cycloheximide (CHX) (B), K562
cells left untreated (lane 1) or treated for 2 h with MG132 alone
(lane 2) or with MG132 and cycloheximide (lane 3) (C), and K562 cells
left untreated (lane 1) or treated with MG132 for 6 h and allowed
to recover for 0 (lane 2), 4 (lane 3), and 10 (lane 4) h in
inhibitor-free medium (D). C, control.
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Incubation in the presence of cycloheximide, to arrest protein
synthesis, abolished both the accumulation and the activation
of HSF2
in ts85 cells shifted to the restrictive temperature (Fig.
3B, lanes 4 and 5), as well as in MG132-treated cells (Fig.
3C).
Likewise, exposure
of hemin-treated cells to cycloheximide resulted
in the rapid loss of
HSF2 DNA-binding activity (Fig.
4A),
which
was accompanied by the conversion of HSF2 from the active
trimeric
state to the inactive dimeric form (Fig.
4C, panels II and
III)
as determined by glycerol gradient analysis. After 2 h in the
presence of both hemin and cycloheximide, all of the HSF2 had
been
converted to the non-DNA binding state (Fig.
4C, panel IV).
Prolonged
exposure to cycloheximide additionally resulted in the
reduction of the
HSF2 level below that observed in control untreated
cells (Fig.
3B and
C and Fig.
4A). Both the loss of HSF2 DNA-binding
activity and the
decreased levels of HSF2 protein observed with
cycloheximide treatment
of hemin-induced K562 cells did not occur
in the presence of MG132
(Fig.
4B). The correlation of HSF2 activity
with HSF2 protein levels is
also observed upon reversal of proteasome
inhibition. Incubation of
K562 cells in MG132-free medium following
a 6-h treatment caused HSF2
DNA-binding activity and HSF2 protein
levels to diminish (Fig.
3D).
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FIG. 4.
Inhibition of protein synthesis results in a loss of
HSF2 DNA-binding activity and of HSF2 protein levels. (A) Gel mobility
shift (upper panel) and immunoblot (lower panel) assays of whole-cell
extracts from K562 cells left untreated (lane 1) or induced with hemin
for 12 h and treated with cycloheximide (CHX) for 0 (lane 2), 30 (lane 3), or 120 (lane 4) min. (B) The effects of simultaneous
inclusion of cycloheximide and MG132, for 0 (lane 1), 30 (lane 2), and
120 (lane 3) min, on hemin-induced cells were also assessed. (C)
Glycerol gradient fractionation (55) of K562 cell extracts
from control cells (I) and from cells induced with hemin for 12 h
(II to IV) and treated with cycloheximide for 0 (II), 30 (III), or 120 (IV) min. Fractions were collected from the top to the bottom of the
gradients (fractions 2 to 16). The positions corresponding to dimeric
and trimeric HSF2 are shown. The S values from protein standards are
indicated (cytochrome c, 1.9S; bovine serum albumin, 4.3S;
alcohol dehydrogenase, 7.4S).
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As these results suggested that HSF2 was labile, the half-life of HSF2
was determined by quantitation of HSF2 protein levels
in K562 cells at
different times following the addition of cycloheximide.
Half-lives of
60 min for human HSF2 (Fig.
5) and 70 min
for mouse
HSF2 were determined. By comparison, HSF1 is a stable protein
whose levels did not change during the time course of this experiment
(data not shown).
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FIG. 5.
Estimation of HSF2 half-life. Hemin-treated K562 cells
were treated with cycloheximide, and samples were taken at various time
points up to 4 h of treatment. Cell extracts were prepared, and
10-µg amounts were used for SDS-PAGE and immunoblot analyses. The
HSF2 protein visualized by ECL was quantitated by scanning
densitometry. Data compiled from 12 experiments (correlation
coefficients, >0.995) are shown. The half-life of HSF2 is calculated
to be 60 min from a logarithmic plot of percentages of original HSF2
protein versus time (in minutes).
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The increased level of HSF2 protein observed upon inhibition of
proteasome activity may result either from inhibition of HSF2
degradation or from the increased synthesis of HSF2, or both.
By using
a pulse-chase metabolic labeling protocol and immunoprecipitation
analysis, HSF2 synthesis was examined under conditions of MG132
treatment. Levels of HSF2 synthesis increased twofold for K562
cells
and sevenfold for MEF within the time course examined. The
immunoprecipitation results for MEF demonstrate increased synthesis
of
both
and
HSF2 isoforms (Fig.
6A).
Upon removal of MG132
from the medium of the tissue culture cells, the
rate of HSF2
synthesis decreased markedly (data not shown), which
partially
explains the return to control levels of HSF2. Pulse-chase
analysis
of HSF2 protein in MEF (Fig.
6B) revealed loss of both HSF2
isoforms
under normal conditions (lane 2). In the presence of MG132,
however,
HSF2 levels were maintained (Fig.
6B, lane 3). These results
provide
an explanation for the accumulation of HSF2 protein, which
occurs
prior to the increased synthesis of HSF2 (Fig.
6A, lane 2).
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FIG. 6.
Elevated synthesis and decreased degradation of HSF2
upon proteasome inhibition. (A) Control MEF (lane 1) and MEF treated
with MG132 for 2 (lane 2) and 6 (lane 3) h were pulse-labeled for 15 min, following which cell extracts were prepared for use for
immunoprecipitation (upper panel) and immunoblot (lower panel) analyses
as described above. The labeled proteins were visualized by
fluorography and quantitated by PhosphorImager analysis. The labeled
protein band appearing above 208 kDa represents a nonspecific
interaction with the antibodies. (B) MEF treated with MG132 for 4 h were pulse-labeled for 15 min and incubated in complete medium with
(lane 3) or without (lane 2) MG132 for an additional 4 h. Cell
extracts were prepared and used for immunoprecipitation analyses as
described above.
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Inhibition of proteasome activity results in induction of heat
shock gene expression.
To determine whether activation of HSF2
DNA-binding activity leads to the expression of the known heat
shock-regulated genes, we used a quantitative reverse transcription-PCR
multiplex assay which uses oligonucleotide primers specific for the
genes encoding the cytosolic and nuclear chaperones Hsp90, Hsp70,
Hsc70, and Hsp27, the endoplasmic reticulum chaperone Grp78, and the
mitochondrial chaperones Hsp75 and Hsp60. Of these members of the heat
shock gene family, the expression of Hsp90, Hsp70, Hsc70, and Hsp27 mRNAs was induced three- to fivefold, that of Hsp60 and Grp78 mRNAs was
induced twofold, and Hsp75 expression was unaffected in MG132-treated
K562 cells (data not shown). The levels of HSF2 mRNA, in comparison, do
not increase with MG132 treatment (data not shown). These results are
consistent with those of previous studies showing that the Hsp90 and
Hsp70 genes, and not the HSF2 gene (55), were
transcriptionally induced upon hemin treatment of K562 cells
(56) and that Hsp70 mRNA levels increased upon MG132
treatment of HepG2 cells (67). The inhibition of proteasome activity, therefore, has broad and nonselective effects as a stress inducer and leads to the activation of the same set of genes known to
be regulated by HSF1.
The induction of heat shock protein synthesis in MG132- and
lactacystin-treated cells was examined following incubation with
Tran
35S label and analysis by one and two-dimensional
SDS-PAGE and Western
blotting. Exposure of K562 cells and other
mammalian cell lines
(data not shown) to either proteasome inhibitor
resulted in the
elevated synthesis of Hsp70 and Hsp90 (Fig.
7A), which corresponded
to a 20-fold
increase in Hsp70 levels and a 12-fold induction
of Hdj-1 (Fig.
7B and
C). These results are supported by recent
observations with yeast,
where inhibition of proteasome function
resulted in induction of heat
shock gene expression (
31). Analysis
by two-dimensional PAGE
revealed that treatment by MG132 or heat
shock led to the induced
synthesis of a common set of proteins
(Fig.
7E and F). In addition,
MG132 treatment specifically induced
the synthesis of two proteins of
approximately 35 kDa which were
not detected following heat shock.
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FIG. 7.
Induction of heat shock proteins in K562 cells by
proteasome inhibitor treatment. (A) 35S-labeled cell
extracts from pulse-labeled cells analyzed by SDS-10% PAGE. Cells
were left untreated (lane 1), treated with 10 µM MG132 for 2 or
6 h (lanes 2 and 3), treated with 10 µM lactacystin (Lac) for 2 or 6 h (lanes 4 and 5), or heat shocked (HS) at 42°C for 1 h (lane 6). (B) Hsp70 immunoblot of cell extracts using the mouse
monoclonal antibody 4G4. From left to right, treatments correspond to
those described for panel A, lanes 1 through 6. (C) Hdj-1 immunoblot of
cell extracts using rabbit polyclonal sera raised against Hdj-1. From
left to right, treatments correspond to those described for panel A,
lanes 1 through 6. (D through F) Two-dimensional protein gel analysis
of 35S-labeled cell extracts left untreated (D), treated
with 10 µM MG132 for 6 h (E), or heat shocked at 42°C for
1 h (F). The first dimension was isoelectric focusing generating a
gradient from pH 3 to 10. The second dimension was SDS-10% PAGE. Open
arrowhead, location of Hsc70; solid arrowhead, location of Hsp70;
arrow, location of Hsp90. The circled proteins of approximately 35 kDa
are induced preferentially upon MG132 treatment. The protein spot
labeled a corresponds to actin.
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DISCUSSION |
Activation of HSF2 upon down-regulation of the
ubiquitin-proteasome pathway not only reveals that the inducible
expression of heat shock genes responds to changes in protein turnover
but establishes a novel role for HSF2. Although previous studies on HSF2 activation suggested a role as a development- and
differentiation-specific factor, a puzzling feature was the ubiquitous
expression of HSF2 in different mammalian tissues or tissue culture
cell lines, where it was maintained in an inert state (37, 38,
65). The evidence that HSF2 was inducibly regulated was based on
observations in human K562 cells that HSF2 DNA-binding and
transcriptional activities were induced by hemin (55, 56,
58). Since hemin is known to cause nonterminal erythroid
differentiation of K562 cells, these observations were interpreted to
provide support for a role of HSF2 in differentiation rather than as a
redundant stress-regulated HSF. However, since hemin was also known to
have the biochemical property of inhibiting proteasome activity, and
since we have demonstrated here, using proteasome inhibitors, that HSF2
activation occurs in a cell type-independent manner, these results
suggest a common regulatory pathway for HSF2, perhaps similar to the
universal activation of HSF1 by heat shock. Ubiquitination and
proteasome activities are themselves modulated during stress (13,
22, 24, 52, 62) and during development and differentiation
(25, 53, 54, 62). Furthermore, activation of HSF2 in the
mouse ts85 cell line, which carries a conditional mutation in E1,
reveals that even though ubiquitination is not inhibited completely at the nonpermissive temperature in these cells (8), the
down-modulation of ubiquitination obtained is sufficient to regulate
HSF2 activity. In addition, our results explain the previously observed
expression of the hsp70 and hsp105 heat shock genes in ts85 cells at
the nonpermissive temperature (5, 21).
HSF2 is a short-lived protein, and activation of HSF2 is accompanied by
its increased synthesis and decreased degradation, the consequence of
which is the accumulation of HSF2. These features suggest that the
regulation of HSF2 has features reminiscent of the Escherichia
coli heat shock promoter-specific 
32 subunit of RNA
polymerase. Under normal conditions of cell growth, 32
is a short-lived protein (59); upon heat shock,
32 levels increase, principally due to decreased
degradation by the FtsH protease, and hence increased protein
stability, which ensures that the heat shock genes are induced
(23, 59, 60). The posttranscriptional regulation of HSF2
presented here distinguishes this member of the HSF family from its
long-lived counterpart, HSF1. Although we have not detected
polyubiquitinated forms of HSF2 when proteasome activity is inhibited,
nevertheless, this is suggested by the activation of HSF2 in the
ubiquitination-deficient ts85 cell line. Arrest of proteasome activity
also causes an increase in HSF2 protein synthesis, while HSF2 message
levels are unaffected (reference 55 and data not
shown). The correlation between HSF2 protein accumulation and
activation is also observed when HSF2 is overexpressed by transient
transfection (14).
The association between HSF2 and the dynamic state of the proteasome
reveals a certain degree of regulatory specificity, although this
distinction is not absolute, as HSF1 was also detected in a partially
activated state. The level of HSF1 contribution to the total amount of
HSF activity induced when proteasome activity is down-regulated varies
widely among cells of different species and tissue origins. In K562
cells, for example, hemin treatment results in negligible levels of
HSF1 activation; furthermore, the slow kinetics of HSF2 activation and
heat shock gene expression reflects the extended period required for
HSF2 levels and proteasome substrates to accumulate. However, in
contrast, the proteasome inhibitors MG132 and lactacystin result in an
immediate arrest of proteasome activity, which results in the rapid
accumulation of abnormal proteins destined for proteasomal degradation.
Although these events might be expected to result in the complete
activation of HSF1, as a result of the appearance and accumulation of
misfolded proteins destined for degradation, we observe that it is
principally HSF2 which is activated. Variable levels of HSF1
coactivation are observed in different cell lines, which suggests a
regulatory overlap between HSF1 and HSF2 to ensure high levels of
chaperones. Consistent with this suggestion, we have observed that
stresses, such as amino acid analogs, which lead to the chronic
appearance of misfolded proteins result in the complete activation of
HSF1 and partial activation of HSF2 (data not shown).
There is a growing body of information to support a role of the heat
shock response as a component of the protein-degradative machinery
(19, 22, 52). A number of proteases and components of
proteolytic pathways are heat shock-induced proteins, including La in
E. coli (17, 44), eukaryotic ubiquitin (3,
14), and the ubiquitin-conjugating enzymes UBC 4 and UBC 5 (51). Proteasome inhibition results in expression of heat
shock proteins (4, 31, 67), and there are several lines of
evidence for chaperones in ubiquitin-proteasome-mediated protein
degradation. For instance, a ubiquitin-processing enzyme was identified
as a suppressor of certain mutations of Hsp70 (7); Hsp90
protects the proteasomal catalytic core against inactivation by
oxidative stress, while also modulating its proteolytic activity
(6, 61, 64); and mutations in the yeast DnaJ homologs Ydj-1
and Sis affect the ubiquitination of abnormal and short-lived proteins and proteasomal digestion of ubiquitinated proteins, respectively (32, 52). Direct association of chaperones with proteasomal substrates has also been detected and implicated in the determination of substrate fates. For example, the ubiquitin-dependent degradation of
certain protein substrates in in vitro reticulocyte lysates was shown
to be strongly influenced by the levels of Hsc70, with which these
substrates were shown to interact (1). In similar in vitro
lysate systems, the nature of the association of selective substrates
with the Hsp90 heterocomplex resulted in either of two fates, refolding
or proteasomal degradation, with prolonged chaperone association
(induced by use of the drug herbimycin A) leading to increased
degradation (49, 50). There is also in vivo evidence that
chaperone association with a yeast proteasomal substrate, Cln3, is
required for efficient phosphorylation, which necessarily precedes the
ubiquitination of this substrate (66). These observed
molecular chaperone associations with substrates as they undergo
polyubiquitination may be important if such extreme forms of
posttranslational modifications lead to the accumulation of nonnative
proteins. Consistent with this suggestion, we have detected the
association of bulk polyubiquitinated proteins with induced Hsp70
and Hsp90 during proteasome inhibition (35a). These interactions are specific and are released in the presence of ATP. Upon
reversal of proteasomal inhibition, the levels of polyubiquitinated substrates which associate with Hsp70 and Hsp90 are dramatically reduced, presumably related to the reduction in polyubiquitinated proteins in the cells. The transient association of ubiquitinated substrates with the chaperones suggests that the chaperone-associated proteins are targeted for degradation. In support of this hypothesis, the targeting for proteasomal digestion of a specific polyubiquitinated substrate, apolipoprotein B100, has been shown to be regulated by its
association with Hsp70 (16).
An attractive proposal for the HSF family is that the coordinated
efforts of multiple HSFs provide chaperone coverage for the diverse
cellular events which cause nonnative proteins to appear and ensure
that their fates as refolded proteins or degraded products have been
determined. We suggest that HSF2 functions as the inducible regulator
at the point where misfolded proteins have been marked for degradation,
thus ensuring a need for the continued inducible expression of
chaperones. These results reveal that HSF activity, and hence
chaperones, are required for both the birth and the death of proteins.
| |
ACKNOWLEDGMENTS |
These studies were supported by a grant from the NIH to
R.I.M. A.M. is a Fellow of the American Heart Association, Chicago Affiliate, and S.K.M. was supported by a U.S. Army Breast Cancer Training Grant.
We thank M. Rechsteiner, A. Ciechanover, A. Haas, A. Goldberg, L. Hicke, and W. J. Welch for their generosity with antibody reagents
and advice, and K. Klyachko, M. Kline, J. Potter, S. Satyal, Y. Shi,
and L. Tai for their comments on the manuscript.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biochemistry, Molecular and Cell Biology, Northwestern University, 2153 North Campus Dr., Evanston, IL 60208. Phone: (847) 491-3340. Fax: (847)
491-4461. E-mail: r-morimoto{at}nwu.edu.
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Molecular and Cellular Biology, September 1998, p. 5091-5098, Vol. 18, No. 9
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Abstract
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