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J. Biol. Chem., Vol. 275, Issue 32, 24970-24976, August 11, 2000
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,From the Centro de Investigaciones Biológicas, Consejo Superior de Investigaciones Científicas, 28006 Madrid, Spain
Received for publication, November 10, 1999, and in revised form, April 18, 2000
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Infection of HeLa cells with
adenovirus-carrying HSF1+ cDNA, which encodes a
mutated form of HSF1 with constitutive transactivation capacity,
increased multidrug resistance 1 (MDR1) mRNA level and P-glycoprotein (P-gp) cell surface content and stimulated rhodamine 123 accumulation and vinblastine efflux activity. On the other hand,
infection with adenovirus-carrying HSP70 and
HSP27 cDNAs did not increase MDR1/P-gp
expression. HSF1 regulates MDR1/P-gp expression at the
transcriptional level, since HSF1+ bound the heat-shock
consensus elements (HSEs) in the MDR1 gene promoter and
also activated the expression of an MDR1 promoter-driven reporter plasmid (pMDR1( The acquisition of the multidrug resistance
(MDR)1 phenotype, defined as
increased resistance against cytotoxic drugs with unrelated structures,
represents one of the major obstacles for chemotherapy of tumors and
other malignancies. One of the mechanisms that may account for MDR is
the surface accumulation of the P-glycoprotein (P-gp, also called the
multidrug transporter), which blocks the influx and/or increases the
efflux of many hydrophobic agents, including some of the most commonly
used anticancer drugs (for a review, see Ref. 1). In humans, P-gp is
encoded by the MDR gene family, composed of two members,
only one of which (MDR1) seems to be functionally
linked to the development of the MDR phenotype (2). P-gp is expressed
in some normal tissues, such as epithelial cells of kidney, liver,
pancreas, and intestinal mucosa and capillaries of brain and testis. In
these tissues, P-gp probably plays a physiological role, promoting the
excretion of xenobiotics or preventing their absorption and also
possibly acting as a chloride channel (reviewed in Refs. 1 and 3). As a
consequence, cancers derived from these tissues may constitutively express P-gp and be intrinsically drug-resistant. However, in most
cases P-gp-derived resistance is acquired during chemotherapy, e.g. in breast, bladder, lung, and ovary tumors, among
others (for a review, see Ref. 3). Prolonged exposure to cytotoxic drugs may lead to the selection of cells with MDR1 gene
amplification, at least under in vitro conditions (2, 4-6).
However, even when amplification occurs, it does not always adequately
explain the increased P-gp expression and drug resistance (6, 7). On
the other hand, P-gp expression may also be de novo induced by short term exposures to cytotoxic agents such as UV light (8), actinomycin D (9), chemotherapeutic drugs (10), and inducers of the
stress response (11, 12).
The heat-shock transcription factors (HSFs) were originally
characterized as regulators of the expression of heat-shock protein (HSP) genes, through the binding to specific sequences
("heat-shock elements," or HSEs) present in the promoter of these
genes. The HSF family contains three members in humans, namely HSF1,
HSF2, and HSF4 (13-15), among which HSF1 is specifically responsible for the stress-mediated HSP induction (16, 17). In unstressed cells,
HSF1 is present in the cytoplasm as a monomer or forming heteromeric
complexes. Upon treatment with stress inducers, HSF1 homotrimerizes,
translocates to the nucleus, and binds the HSE (16, 17) to further
acquire the transactivation capacity (18). Indirect proofs have
suggested that HSFs could also participate in MDR1 gene
expression. In fact, (a) HSEs have been identified in the
MDR1 gene promoter (11, 12); (b) typical stress
inducers such as heat-shock and arsenite, which induce HSP
gene expression, also induce MDR1 gene expression in some
cell types (11, 12); (c) some multidrug-resistant cell lines
exhibit constitutively high HSF-DNA binding activity (19); and
(d) quercetin, which inhibits HSF-HSE binding, also inhibits
HSF-DNA binding and P-gp expression in multidrug-resistant cells (20).
However, the problem is far from being clear, since (a) some
work suggests that the activation of MDR1 expression by
heat-shock and other stressing agents may be mediated by DNA sequences
and transcription factors other than HSE and HSFs (21-23);
(b) the possibility cannot be excluded that MDR1
gene induction by stressing agents, instead of being a direct response,
is mediated by increased HSPs expression; and (c) even if
HSFs directly regulate MDR1 gene expression, it is not known
which member of the family is actually implicated.
In the present work, we analyzed the regulation of MDR1 gene
expression by HSF1 using direct gene transfer procedures. This was made
possible by the use of specific HSF1 mutants, namely a construction
encoding an active mutant (HSF1+) (a deleted form of HSF1
with constitutive binding and transactivation capacities) and a
construction encoding a dominant negative mutant (HSF1 Cell Culture and Treatments--
All components for cell culture
were obtained from Life Technologies, Inc. (Life Technologies). Sodium
arsenite and sodium butyrate were obtained from Merck, and etoposide
was from Sigma. Human HeLa cells and human 293 cells were cultured in
Dulbecco's modified Eagle's medium supplemented with 10% (v/v) fetal
calf serum and antibiotics in a humidified 5% CO2
atmosphere at 37 °C. Sodium arsenite and sodium butyrate were
dissolved before use in Dulbecco's modified Eagle's medium at 100 mM. Etoposide was dissolved in Me2SO at
20 mM and stored at Plasmids and Transfection Assays--
Expression plasmids were
derived from pcDNA3.1 (Invitrogen Corp., Carlsbad, CA) by insertion
of cDNA genes for human HSF1 (HSF1wt), HSF1d202-316
(HSF1+), or bacterial
Transfection was performed using the LipofectAMINETM
reagent (Life Technologies). Cells were seeded in 12-well plates at a
density of 105 cells/well. The next day, the cells were
incubated for 5 h with 1 ml of culture medium containing 225 ng of
either pGL2B, pMDR1( Viral Vectors and Infection Assays--
Recombinant adenovirus
vectors were generated by co-transfection of human 293 cells with
plasmid AC CMV pLpa SR( Flow Cytometry Assays--
The cells were detached from culture
dishes by a brief incubation with PBS containing 0.04% EDTA at
37 °C, after which they were collected by centrifugation, washed,
and resuspended in PBS at the desired concentration.
For determination of P-gp surface expression, indirect
immunofluorescence assays were carried out using a mouse anti-human P-gp mAb (clone UIC2, Immunotech, Marseille, France). Cells were incubated for 30 min at 4 °C with the mAb and then washed three times with PBS and incubated again for 15 min at 4 °C with
fluorescein isothiocyanate-conjugated anti-mouse IgG (Amersham
Pharmacia Biotech). After washing the cells, the fluorescence was
estimated by flow cytometry, using an EPICS KL flow cytometer (Coulter,
Miami, FL)
The rhodamine 123 accumulation assay was carried out exactly as
described by Frommel et al. (28).
Vinblastine Efflux Assay--
The procedure was basically the
same as described by Frommel et al. (28). After 24 h of
infection, triplicate cell samples were labeled for 18 h in
culture medium containing 0.5 µCi/ml [3H]vinblastine
(12.5 Ci/mmol, Amersham Pharmacia Biotech) and then washed three times
with PBS and incubated again with fresh,
[3H]vinblastine-free culture medium. At 15, 30, and 60 min, the whole medium was removed and replaced, and aliquots of the
medium were used to determine the amount of effluxed vinblastine by
scintillation counting. To determine the amount of vinblastine
remaining in the cells, at the end of the experiment the cells were
washed and lysed with PBS containing 0.1% Triton X-100. These data
were used to determine the percentage of vinblastine associated
with the cells at each time point.
Immunoblot Assays--
Cell lysis, electrophoretic separation,
blotting onto Immobilon-P membranes (Millipore Corp., Bedford, MA), and
immunological detection of proteins were carried out essentially as
described previously (29). The antibodies used were mouse anti-human
HSP70 monoclonal antibody (clone C92F3A-5; StressGen Biotechnologies Corp., Victoria, Canada); mouse anti-human HSP27 monoclonal antibody (clone G3.1; StressGen); and mouse anti-chicken RNA Blot Assays--
Total RNA was prepared using an
Ultraspect-II RNA isolation kit (Biotech Laboratories, Inc., Houston,
TX), following the procedure described by the manufacturer. All other
conditions, including the source and preparation of the
HSP70- specific cDNA probe, were as described previously
(30). Other probes were the 1.4-kilobase MDR1-specific EcoRI fragment of pHDR54
plasmid (Ref. 31; American Type Culture Collection, number 61361) and
the entire pTRI RNA 28S plasmid, which recognizes 28 S rRNA (Ambion,
Inc., Austin, TX).
Gel Shift Assays--
Whole cell extracts were prepared as
described by Zuo et al. (18). The partially complementary
oligonucleotides 5'-GCGAAACCCCTGGAATATTCCCGACCTGGC-3' and
5'-GGGCCAGGTCGGGAATATTCCAGGGGTTTCG-3' (corresponding to the human
HSP70 promoter) (32);
5'-GCCAGAACATTCCTCCTGGAAATTCAA-3' and 5'-CAGGTTGAATTTCCAGGAGGAATGTT-3'
(corresponding to the human MDR1 promoter) (11);
5'-GCCAGGACATCCCTCCTGGAAATCCAA-3' and 5'-CAGGTTGGATTTCCAGGAGGGATGTC-3' (corresponding to a mutated MDR1 promoter); and
5'-GGCTAGTGATGAGTCAAGCCGGATC-3' and 5'-GGGATCCGGCTTGACTCATCACTAG-3'
(containing AP-1 binding sites) were prepared and, when required,
labeled with [ MDR1/P-gp and HSP Expression--
It was earlier reported that the
HSF1+ mutant was able to constitutively induce the
expression of endogenous HSP genes in the absence of stress
(27). Hence, this mutant was used to investigate whether HSF1 regulates
MDR1/P-gp expression. With this in mind, we measured the
MDR1 RNA level at different times after infection with
Ade-HSF1+. It was observed that HSF1+ caused an
increase in MDR1 RNA level, which was first detected at 12 h of
infection and followed thereafter (Fig.
1A). Ade-HSF1+
infection also increased HSP70 mRNA level (included as a positive control), but in this case the increase was already detected at 6 h (Fig. 1A). MDR1 and HSP70 mRNAs were undetectable in
both noninfected cells and cells only infected with the viral vector (Ade-infected cells). The HSF1+-mediated induction of
MDR1/P-gp expression was corroborated at the protein level.
In fact, a clear increase in P-gp cell surface accumulation could be
detected at 24 h (result not shown) and 48 h of infection
with Ade-HSF1+, when compared with noninfected and
Ade-infected cells (Fig. 1B).
Since the increase in HSP70 mRNA level apparently preceded the
increase in MDR1 RNA level in Ade-HSF1+-infected cells
(Fig. 1A), we questioned whether the HSF1-provoked stimulation of MDR1/P-gp expression could be a mere
consequence of HSP accumulation. To investigate this possibility, cells
were infected with Ade-HSF1+ as well as with viral vectors
carrying inducible HSP70 and HSP27 cDNAs (Ade-HSP70 and Ade-HSP27,
respectively). Immunoblot assays using anti-HSP70 and anti-HSP27
antibodies proved that, as expected, infection with Ade-HSP70 increased
the level of HSP70 protein; infection with Ade-HSP27 increased the
level of HSP27 protein; infection with Ade-HSF1+ increased
the level of both HSP70 and HSP27; and Ade-infection was ineffective
(Fig. 2A). When P-gp cell
surface expression was measured, it was found to be greatly increased
by Ade-HSF1+ infection but only slightly augmented by
Ade-HSP70 and Ade-HSP27 infection (Fig. 2B). RNA blot assays
confirmed the increase in MDR1 mRNA by Ade-HSF1+ but
not by Ade-HSP70 or Ade-HSP27 (Fig. 2C). Hence, the increase in MDR1/P-gp expression in HSF1+-infected cells
may not be adequately explained as a consequence of HSPs
accumulation.
Rhodamine Accumulation and Vinblastine Efflux--
Earlier reports
indicated that P-gp cell surface expression could be increased without
modification in drug accumulation and/or efflux (33, 34). To test the
functionality of the HSF1-mediated increase in P-gp, we comparatively
measured rhodamine accumulation as well as vinblastine efflux activity
in Ade-infected and Ade-HSF1+-infected cells. Some of the
obtained results are indicated in Fig. 3.
Under the used experimental conditions, a subpopulation of cells with
decreased rhodamine 123 accumulation was observed in
Ade-HSF1+-infected cultures, in comparison with
Ade-infected cultures (Fig. 3A). In a similar manner,
Ade-HSF1+ infection accelerated the rate of vinblastine
efflux, when compared with Ade-infected cultures (Fig. 3B).
Hence, HSF1 activity sufficed to stimulate the expression of the
multidrug resistance phenotype, as measured by altered P-gp transport
activity.
Transcriptional Regulation--
We queried whether the
HSF1-mediated increase in MDR1/P-gp expression was regulated
at the transcriptional level. This was first investigated by means of
gel shift assays, using a MDR1 promoter-derived
oligonucleotide. Although the MDR1 promoter contains multiple HSEs (11), it was reported that those present in the
The results obtained by gel shift assays were corroborated and extended
by transient transfection assays. For this purpose, we used a
MDR1 promoter-driven luciferase gene construction
(pMDR1( Effect of Stress Inducers--
While the preceding results
demonstrated that MDR1/P-gp expression is susceptible to regulation by
HSF1, they did not prove that HSF1 is in fact responsible for MDR1
induction under stressing conditions. To investigate this possibility,
cells transfected with either pMDR1(
Finally, we wanted to know whether HSF1 could also mediate the
induction of MDR1/P-gp by other agents. With this aim, cells co-transfected with pMDR1( The role of MDR1/P-gp expression as one of the main
determinants of the MDR phenotype is of great importance in
understanding the mechanisms of the regulation of this gene and to
generate strategies to inhibit its expression and/or function. The
human MDR1 promoter contains multiple elements, which point
to a complex regulation. Thus, it has been demonstrated that
MDR1 is susceptible to positive regulation by the Sp1 (35,
36), AP-1 (37), NF-IL6 (38), NF-Y (24), EGR1 (39), YB-1 (23),
and MEF-1 (40) transcription factors; to negative regulation by
cross-coupling of the NF- Although the only goal of the present work was to analyze the
MDR1 gene regulation by HSF1, the obtained results may also have some clinical relevance. Among the different strategies conceived to overcome the P-gp-mediated MDR (for a review, see Ref. 44), those
commonly used consist in the administration of agents such as
verapamil, cyclosporin A, and related compounds, which bind P-gp and
block its transport activity. By contrast, the attempts to specifically
inhibit MDR1 expression have been of little effect until
now. In this regard, our present results indicate that it could be
possible to prevent MDR1/P-gp expression by inhibiting HSF1-HSE binding or HSF1-directed transactivation. For instance, antitumor drugs rapidly induce MDR1/P-gp expression in
cultured cells (10), and MDR1/P-gp is actually increased
after chemotherapy in different cancers (e.g. acute
leukemia, breast cancer, neuroblastoma, and pheochromocytoma, among
others). If such induction is mediated at least in part by HSF1, as
indicated by our experiments using etoposide, then it could be
attenuated by gene transfer procedures using the HSF1
1202)). In addition, heat-shock increased pMDR1(1202) promoter activity but not the activity of a similar reporter plasmid with point mutations at specific HSEs, and the heat-induced increase was totally inhibited by co-transfection with an
expression plasmid carrying HSF1
, a dominant negative
mutant of HSF1. The stress inducers arsenite, butyrate, and etoposide
also increased pMDR1(1202) promoter activity, but the increase was
not inhibited (in the case of butyrate) or was only partially inhibited
(in the case of arsenite and etoposide) by HSF1. These
results demonstrate that HSF1 regulates MDR1 expression, and that the HSEs present in the 315 to 285 region mediate the heat-induced activation of the MDR1 promoter. However,
other factors may also participate in MDR1 induction by
stressing agents.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
)
(a deleted form that constitutively binds the HSP gene
promoters but is unable to transactivate, even under stressing
conditions) (18).
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
20 °C. For treatments, HeLa cells
were either placed in a bath for 2 h at 43 °C and then allowed
to recover for 4 h at 37 °C; treated for 4 h with 100 µM sodium arsenite and then washed twice with Dulbecco's
modified Eagle's medium medium and allowed to recover for 4 h in
the absence of the drug; or continuously treated for 24 h with 5 mM sodium butyrate or 200 µM etoposide.
-galactosidase or derived from
pcDNA1 (Invitrogen Corp.) by insertion of the cDNA gene for
human HSF1d453-523 (HSF1) (see Ref. 18 and references
therein). The reporter plasmid pMDR1(1202) was produced by inserting
a MDR1 promoter sequence (1202 to +118) into the luciferase vector
pGL2B (Promega, Madison, WI) (24). Mutagenesis of the 315 to 285
sequence of the MDR1 promoter was made by sequential polymerase chain
reaction steps from plasmid pMDR1(1202). The original sequence
5'-GCCAGAACATTCCTCCTGGAAATTCAACCTG-3' was changed to
5'-GCCAGGACATCCCTCCTGGAAATCCAACCTG-3',
where the mutated bases are underlined. For this purpose, complementary oligonucleotides A (5'-GCCAGGACATCCCTCCTGGAAATCCAA-3') and B
(5'-CAGGTTGGATTTCCAGGAGGGATGTC-3') were designed. At the same time,
oligonucleotides F (5'-GTAACTGAGCTAACATAAC-3') and R
(5'-TTACTTAGATCTCGAGCTAGC-3'), corresponding to the
polylinker flanking regions of plasmid pGL2B, were also synthesized and
used as primers. Using the pMDR1(1202) plasmid as a template, single PCRs with A and R, as well as B and F primers were performed. The
amplification products were annealed with each other and extended by
mutually primed synthesis. The fragment was then amplified by a second
PCR step, in the presence of primers F and R. The product was digested
with SmaI and inserted into pGL2B. The resulting reporter
plasmid was designated as pMDR(1202)mut. The site-directed mutagenesis was verified by DNA sequencing. pHSP70-luc, a plasmid containing a highly inducible human HSP70B promoter-driven luciferase gene, was kindly supplied by Dr. R. Voellmy (Dept. of Biochemistry and
Molecular Biology, University of Miami School of Medicine, Miami, FL).
1202), pHSP70-luc, or pMDR1(1202)mut plasmids,
225 ng of expression plasmids (when required), 50 ng of the
-galactosidase plasmid, and 2 µl of LipofectAMINETM
reagent. Following transfection, the mixture was removed, and the cells
were incubated under standard conditions for 16 h, after which
they were either harvested or subjected to heat-shock. Luciferase assays were performed using a Luciferase Assay System Freezer-1 Pack
kit (Promega) and a TD-20/20 Luminometer (Turner Designs, Sunnyvale,
CA), the values being normalized in relation to protein concentration.
Internal normalization of the transfection efficacy was performed using
a chemiluminiscent reporter gene assay system to detect
-galactosidase (Tropix Inc., Bedford, MA).
) containing, or not containing, the cDNAs
for human HSF1d202-316 (Ade-HSF1+), inducible rat HSP70
(Ade-HSP70), or human HSP27 (Ade-HSP27), and the infectious plasmid
JM17 (25-27). HeLa cells (at about 50% confluence) were infected at a
multiplicity of infection of 5-10 PFU/cell.
-tubulin monoclonal antibody (Amersham Pharmacia Biotech).
-32P]dCTP as earlier reported (29). For
binding reactions, cell extracts containing 5 µg of proteins were
mixed with 10 µl of Kingston buffer (120 mM KCl, 4 mM MgCl2, 0.24 mM EDTA, 0.6 mM 1, 4-dithiothreitol, 0.6 mM
phenylmethylsulfonyl fluoride, 24% (v/v) glycerol, 24 mM
HEPES, pH 7.9), 4 µg of salmon sperm DNA, and water to a final volume
of 18 µl. After preincubating for 15 min on ice, 2 µl of labeled
probe (approximately 10,000 cpm) was added, and the incubation
followed for 15 min at room temperature. To prove the specificity of
binding, when required the reactions were carried out in the presence
of a 50-fold excess of unlabeled HSP70, MDR1, or AP-1 probes or in the
presence of anti-HSF1 antibody (rabbit anti-human HSF1 polyclonal
antibody; StressGen) or preimmune serum. The samples were
electrophoresed in 4.5% native polyacrylamide gels, and the gels were
dried and autoradiographed.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
HSF1-mediated induction of
MDR1/P-gp expression. A, total RNA
extracts (35 µg/lane) obtained from noninfected cells
(Cont) and from cells infected for the indicated time
periods with either Ade-HSF1+ or the viral vector
(Ade) were used for Northern blot assays. The same filter
was sequentially hybridized with MDR1-, HSP70- and 28 S rRNA-specific
cDNA probes (the latest one used as a control). B, cell
distribution according to the surface accumulation of P-gp in cultures
infected for 48 h with either Ade-HSF1+ or the viral
vector (Ade), in comparison with untreated cultures
(Cont), as determined by indirect immunofluorescence
combined with flow cytometry. The profiles corresponding to
Ade-infected and control cells totally overlapped. The experiments were
repeated twice (A) or three times (B) with
similar results.
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Fig. 2.
Independence of P-gp expression on HSP70 and
HSP27 accumulation. Cells were either left untreated
(Cont) or infected for 48 h with Ade-HSF1+,
Ade-HSP70, Ade-HSP27, or the viral vector (Ade).
A, After cell lysis, the levels of HSP70, anti-HSP27, and
anti- -tubulin proteins (the latest one used as a control) were
determined by immunoblot using specific antibodies (HSP70
ab, HSP27 ab, and -tub ab).
B, the surface accumulation of P-gp was determined by flow
cytometry. C, the relative levels of MDR1 mRNA and 28 S
rRNA were determined by Northern blot. All other conditions were as in
Fig. 1. The experiments were repeated at least twice with the same
results.
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Fig. 3.
Drug accumulation and efflux.
A, noninfected cells (Cont) and cells infected
for 48 h with either Ade-HSF1+ or the viral vector
(Ade) were loaded with rhodamine 123, and the fluorescence
was determined by flow cytometry. The profiles corresponding to
Ade-infected and control cells totally overlapped. B, cells
infected with Ade-HSF1+ (closed
symbols) or with the viral vector (open
symbol) were labeled with [3H]vinblastine
(Vbl). After washing, the amount of radioactivity effluxed
to the medium was measured at different times of recovery. The graph
indicates the fraction [3H]vinblastine remaining in the
cells at each time in relation to that measured at the end of the
labeling period (0 min of recovery, which was given the arbitrary value
of 100). The approximate values at 0 min of recovery were 10.6 × 104 and 5.1 × 104 cpm/mg of protein for
Ade- and Ade-HSF1+-infected cells, respectively. Each value
represents the mean ± S.D. of three determinations.
315 to
285 region seem to mediate the induction of MDR1 by
arsenite, an inducer of the stress response (12), and hence this
sequence was selected as the MDR1 probe (MDR1wt probe) (Fig.
4A). In addition, a similar
sequence in which point mutations at the HSEs were introduced (MDR1mut
probe) and a HSE-containing HSP70 promoter-derived
oligonucleotide (HSP70 probe) were used as negative and positive
controls, respectively (Fig. 4A). The obtained results are
represented in Fig. 4B. Extracts from
Ade-HSF+-infected cells bound the MDR1wt probe with a
similar pattern as in the case of the HSP70 probe, while no binding was
observed using the the MDR1mut probe. The binding to the MDR1wt and
HSP70 probes was specific, since it was not detected when using
extracts of Ade-infected cells or when the incubation was carried out
in the presence of anti-HSF1 antibody or excess homologous (MDR1wt or
HSP70) probes. On the other hand, it was not affected by excess MDR1mut or heterologous (AP-1) probes.
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Fig. 4.
HSF1 binding to MDR1 and
HSP70 gene promoter sequences. A,
synthetic oligonucleotides corresponding to HSP70 promoter
(HSP70 probe) and the MDR1 promoter, either wild type
(MDR1wt probe) or mutated (MDR1mut probe), used for gel shift assays.
The lines indicate HSE inverted repeats (C-GAA-TTC-G). Note
that the HSP70 probe contains a consensus repeat, while the MDR1 probes
contains two overlapped repeats with some mutated bases (indicated by
asterisks), one affecting the first repeat and two the
second repeat. The mutations provoked to generate the MDR1mut probe are
indicated by circles. B, gel shift assays using
the different probes (bottom), as well as extracts from
noninfected cells (Cont) and cells infected for 12 h
with either Ade-HSF1+ or the viral vector (Ade)
(top). To examine the specificity of binding, some reactions
were carried out in the absence of competitors ( ); in the presence of
anti-HSF1 antibody (+HSF1ab) or preimmune serum
(+PS); and in the presence of a 50-fold excess of unlabeled
MDR1wt (+MDR1wt), MDR1mut (+MDR1mut), HSP70
(+HSP70), and unrelated (+AP-1) probes. Note the
absence of binding with the MDR1mut probe, when compared with MDR1wt
and HSP70 probes. The experiment was repeated twice with similar
results.
1202) plasmid) and a similar construction with the same point
mutations in the 315 to 285 region, which disrupted
HSF1+ binding (pMDR1(1202)mut plasmid). It was found that
pMDR1(1202) activity was greatly increased by co-transfection with
HSF1+, while the same assay caused a much lower increase of
pMDR1(1202)mut activity (Fig. 5). Taken
together, these results demonstrate that HSF1 regulates MDR1
expression at the transcriptional level and suggest that the HSE sites
located in the 315 to 285 region are critical for such a
transcriptional regulation.
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Fig. 5.
HSF1-mediated induction of MDR1
promoter activity. Cells were co-transfected with either a
HSF1+ expression plasmid or the corresponding vector
(pcDNA3.1) plus one of the following reporter plasmids:
pMDR1( 1202), pMDR1(1202)mut, or the corresponding vector (pGL2B).
The cells were lysed, and the luciferase activity was measured and
normalized against -galactosidase activity. The results represent
-fold induction in relation to that obtained by co-transfection with
pcDNA3.1 plus pMDR1(1202), which was given the arbitrary value of
1. The data represent the mean ± S.D. of three
determinations.
1202) or pMDR1(1202)mut were
subjected to heat-shock, which is the most typical stress inducer. It
was observed that heat effectively increased pMDR1(1202) promoter
activity but not pMDR1(1202)mut activity (Fig.
6A). This proved that the HSEs
present in the 315 to 285 region are specifically required for the
heat-provoked induction of MDR1 expression. As a second experimental approach, heat-shock was applied to cells co-transfected with pMDR1(1202) plus one of the following expression plasmids: HSF1
wild type (HSF1wt), which binds the HSE but does not transactivate in
the absence of stress (18); a dominant negative HSF1
(HSF1); or the empty vector (pcDNA3.1). The results
are represented in Fig. 6B. It was observed that heat-shock
activated pMDR1(1202) promoter activity in both pcDNA3.1- and
HSF1wt-transfected cells, while the activation was totally inhibited by
HSF1 transfection. In addition, it was observed that the
basal pMDR1(1202) activity reached similar values in nonheated
HSF1wt-transfected and pcDNA3.1-transfected cells. Taken together,
these results indicate that HSF1 mediates the heat-provoked
activation of MDR1 expression and that the mere binding of
HSF1 does not suffice to transactivate the MDR1 promoter, as
was reported in the case of HSP gene promoters (18).
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Fig. 6.
Induction by heat-shock of
MDR1 promoter activity. A, cells were
transfected with either pMDR1( 1202) or pMDR1(1202)mut reporter
plasmids or the corresponding vector (pGL2B). B, cells were
co-transfected with either pMDR1(1202) or pGL2B plus one of the
following expression plasmids: HSFwt, HSF1, or the
corresponding vector (pcDNA3.1). In all cases, the cells were left
undisturbed (37 °C) or subjected to heat-shock (HS). The
results represent -fold induction in relation to those obtained with
pMDR1(1202)- or pMDR1(1202)mut-transfected cells at 37 °C
(A) or pcDNA3.1 plus pMDR1(1202)-co-transfected cells
at 37 °C (B). The data represent the mean ± S.D. of
three determinations. For other conditions, see the legend to Fig.
5.
1202) plus either HSF1 or
pcDNA3.1 were treated with the stress inducer sodium arsenite, the
differentiation inducer sodium butyrate, and the antitumor drug
etoposide, all of which were reported to activate MDR1
expression in different cell types (10-12, 23, 34). Parallel
determinations were carried out using a HSP70
promoter-driven reporter plasmid (pHSP70-luc) instead of pMDR1
(1202). The obtained results are indicated in Fig.
7. It was observed that arsenite,
butyrate and etoposide increased HSP70 promoter activity,
and the increase was totally inhibited by co-transfection with
HSF1 (Fig. 7A). In this sense, not only
arsenite, but also butyrate and etoposide, may be strictly considered
inducers of the stress response. These agents also increased
pMDR1(1202) promoter activity, but in this case the increase was not
inhibited (butyrate) or was only partially inhibited (arsenite and
etoposide) by HSF1 (Fig. 7B).
View larger version (24K):
[in a new window]
Fig. 7.
Induction of HSP70 and
MDR1 promoter activity by arsenite, butyrate, and
etoposide. A, cells were co-transfected with either the
pHSP70-luc reporter plasmid or the corresponding vector (pGL2B), plus
either the HSF1 expression plasmid or the corresponding
vector (pcDNA3.1). B, cells were cotransfected with
either pMDR1(1202) or pGL2B plus either HSF1 or
pcDNA3.1. In all cases, the cells were left undisturbed
(Untreat) or treated with sodium arsenite, sodium butyrate,
or etoposide. The results represent -fold induction in relation to
cells cotransfected with pcDNA3.1 plus pHSP70-luc (A) or
pcDNA3.1 plus pMDR1(1202) (B) under control
conditions. The data are mean ± S.D. of three determinations. For
other conditions, see the legend to Fig. 5.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
B/p65 and c-Fos factors (41); and to
either positive or negative regulation by p53 (42, 43). Although
earlier reports identified the presence of HSEs in the MDR1
promoter, the present work provides the first direct demonstration that
HSF1 regulates MDR1/P-gp expression and drug transport
activity. Moreover, the HSF1-mediated regulation of MDR1
exhibits some characteristics earlier reported for HSP genes, such as
activation by heat-shock and separate regulation of the HSF1 binding
and transactivation capacities (18). This indicates that
MDR1 may be strictly considered a stress gene. However, the
present results also indicate that the regulation of MDR1
and HSP70 by stress inducers is not identical and suggest
that factors other than HSF1 may account, at least in part, for the
induction of MDR1 by some stressing agents. In fact, while
HSF1 sufficed to explain the activation of the HSP70 promoter by butyrate, arsenite, and etoposide, this factor was either
irrelevant (in the case of butyrate) or insufficient (in the case or
arsenite and etoposide) to fully explain the activation of the
MDR1 promoter by these agents. In this regard, a recent report indicated that the activation of the MDR1 promoter by
butyrate is mediated by the NF-Y (24), and our preliminary observations indicate that its activation by etoposide is partially regulated by
AP-1.2
mutant. The same procedure might help to prevent MDR1
induction by other stressful albeit common clinical situations
(e.g. fever, which might mimic in vivo the effect
of heat-shock in vitro). Moreover, HSF1 might
help to prevent the undesirable induction of HSPs expression. This
later aspect is also interesting, since HSP70 and other HSPs may reduce
the lethality of antitumor drugs and other cytotoxic insults by
preventing apoptosis (for a review, see Ref. 45) and hence provide an
alternative mechanism for drug resistance. A detailed analysis of the
involvement of HSF1 in the regulation of MDR1/P-gp
expression in different tumor cells, and of the different factors that
may contribute to drug resistance is required to define the feasibility
of this hypothesis.
| |
ACKNOWLEDGEMENTS |
|---|
We are greatly indebted to Dr. R. Voellmy (Dept. of Biochemistry and Molecular Biology, University of
Miami School of Medicine, Miami, FL) and Dr. R. Mestril (The
Cardiovascular Institute, Loyola University Medical Center, Maywood,
IL) for Hsp70-luc reporter plasmid, HSF1 expression vectors, and
adenoviral vectors, to Dr. K. W. Scotto (Memorial
Sloan-Kettering Cancer Center, New York, NY) for the
pMDR1(1202) reporter plasmid, to Dr. C. Calés (Dept. de
Bioquímica, Universidad Autónoma, e Instituto de
Investigaciones Biomédicas, CSIC, Madrid) and Dr. E. Páez (Centro de Investigaciones Biológicas, CSIC, Madrid)
for laboratory facilities, and to Drs. R. Voellmy and A. Corbí
(Centro de Investigaciones Biológicas, CSIC) for critical
reading of the manuscript.
| |
FOOTNOTES |
|---|
* This work was supported by Dirección General de Enseñanza Superior e Investigación Científica (Spain) Grant PM97-0144 and Comunidad Autónoma de Madrid (Spain) Grant 08.1/0027/1997.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Present address: Dept. de Bioquímica, Universidad
Autónoma, e Instituto de Investigaciones Biomédicas,
Consejo Superior de Investigaciones Científicas, Arturo
Duperier 4, 28029 Madrid, Spain.
§ Recipient of a predoctoral fellowship from the Dirección General de Enseñanza Superior e Investigación Científica, Spain.
¶ To whom correspondence should be addressed.: Centro de Investigaciones Biológicas, CSIC, Velázquez 144, 28006 Madrid, Spain. Tel.: 34-915644562 (ext. 4247); Fax: 34-915627518; E-mail: aller@cib.csic.es.
Published, JBC Papers in Press, May 17, 2000, DOI 10.1074/jbc.M909136199
2 N. E. Vilaboa, A. Galán, A. Troyano, E. de Blas, and P. Aller, unpublished results.
| |
ABBREVIATIONS |
|---|
The abbreviations used are: MDR, multidrug resistance; HSE, heat-shock element; HSF, heat-shock factor; HSP, heat-shock protein; PBS, phosphate-buffered saline; P-gp, P-glycoprotein; PCR, polymerase chain reaction.
| |
REFERENCES |
|---|
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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