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J. Biol. Chem., Vol. 275, Issue 47, 37181-37186, November 24, 2000
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From the
Received for publication, May 2, 2000, and in revised form, August 1, 2000
Heat shock protein 90 (Hsp90), one of the most
abundant chaperones in eukaryotes, participates in folding and
stabilization of signal-transducing molecules including steroid hormone
receptors and protein kinases. The amino terminus of Hsp90 contains a
non-conventional nucleotide-binding site, related to the ATP-binding
motif of bacterial DNA gyrase. The anti-tumor agents geldanamycin and
radicicol bind specifically at this site and induce destabilization of
Hsp90-dependent client proteins. We recently demonstrated
that the gyrase inhibitor novobiocin also interacts with Hsp90,
altering the affinity of the chaperone for geldanamycin and radicicol
and causing in vitro and in vivo depletion of
key regulatory Hsp90-dependent kinases including v-Src,
Raf-1, and p185ErbB2. In the present study we used
deletion/mutation analysis to identify the site of interaction of
novobiocin with Hsp90, and we demonstrate that the novobiocin-binding
site resides in the carboxyl terminus of the chaperone. Surprisingly,
this motif also recognizes ATP, and ATP and novobiocin efficiently
compete with each other for binding to this region of Hsp90. Novobiocin
interferes with association of the co-chaperones Hsc70 and p23 with
Hsp90. These results identify a second site on Hsp90 where the binding
of small molecule inhibitors can significantly impact the function of
this chaperone, and they support the hypothesis that both amino- and
carboxyl-terminal domains of Hsp90 interact to modulate chaperone activity.
The abundant molecular chaperone Hsp90 mediates the function of
many key regulatory proteins of eukaryotic cells, including steroid
receptors (1-3), mutated p53 (4), and a number of tyrosine and
serine/threonine kinases, among which are members of the Src family
(5), p185ErbB2 (6), cyclin-dependent kinases
Cdk4 and Cdk6 (7), and Raf-1 (8, 9). Hsp90 functions in association
with a number of accessory proteins, including Hsc70,
p60Hop, cyclophilin 40, the immunophilins FKBP 52 and 51, and p23 (2, 10-12).
Functional analysis has revealed that Hsp90 is composed of well
conserved amino- and carboxyl-terminal regions separated by a charged
domain (13, 14). The crystal structure of an amino-terminal fragment of
Hsp90 complexed with ATP has recently been solved (15); ATP binding to
this domain of Hsp90 has also been detected biochemically (13, 16), and
the functional importance of ATP hydrolysis for Hsp90 activity has been
characterized (17, 18). X-ray crystallographic and biochemical studies
have also demonstrated that the natural products geldanamycin
(GA)1 and radicicol both
interact with the amino-terminal nucleotide-binding site on Hsp90 (16,
17, 19, 20), leading to alterations in the conformation and function of
the protein. In contrast to the amino terminus, the crystal structure
of the carboxyl-terminal region of Hsp90 remains undetermined, and
biochemical characterization of this portion of the chaperone suggests
that a complex interaction between this and the amino-terminal domain
is a critical regulatory component of chaperone function (14,
21-23).
We recently reported that novobiocin, an antibiotic previously shown to
bind adjacent to the ATP-binding site of bacterial gyrase B and to
interfere with nucleotide binding (24), was also able to interact with
Hsp90, albeit with lower affinity than with gyrase B, and to disrupt
the chaperone activity of Hsp90 in a manner similar to GA and
radicicol (25). Thus, cells exposed to novobiocin demonstrated rapid
destabilization of various Hsp90 client proteins, including Raf-1,
mutated p53, p60v-Src, and p185ErbB2.
Unexpectedly, however, although novobiocin antagonized Hsp90 binding to
both GA and radicicol, the Hsp90-binding domain of novobiocin appeared
to be distinct from the amino-terminal
GA/radicicol/nucleotide-binding domain (25).
In the current study, we have localized the Hsp90-binding site of
novobiocin to a region overlapping the carboxyl-terminal dimerization
domain of the chaperone. The current data, together with our previous
study (25), emphasize the functional significance of novobiocin binding
to Hsp90, support the possibility that the conformation of Hsp90's
amino terminus can influence the behavior of the carboxyl-terminal
portion of the molecule, and suggest that a previously unrecognized
second nucleotide-binding domain exists in the carboxyl terminus of Hsp90.
Preparation of Hsp90 Constructs and Glutathione S-transferase
(GST) Fusion Proteins--
Full-length chicken Hsp90 In Vitro Transcription and Translation--
Recombinant proteins
were expressed from 1 µg of plasmids by in vitro
transcription/translation using the TNT rabbit reticulocyte lysate kit
(Promega Corp.) in the presence of translation grade [35S]methionine (1458 Ci/mmol, ICN, Costa Mesa, CA), with
the appropriate DNA polymerase and following the manufacturer's
instructions. Aliquots of each reaction (1 µl) were checked for
translation efficiency, and 10-20 µl were diluted in the appropriate
buffer and incubated with either novobiocin-Sepharose or ATP-Sepharose as described below.
Preparation of Novobiocin-Sepharose 6B and the Solid Phase
Novobiocin Binding Assay--
Novobiocin-Sepharose was prepared as
described previously (25, 27). 10-20 µl of in vitro
translate or 4 µg of purified GST-Hsp90 proteins were diluted in 300 µl of buffer B (25 mM Hepes, pH 8, 1 mM EDTA,
10% ethylene glycol, 200 mM KCl) and incubated with
novobiocin-Sepharose (100 µl), with or without preincubation (60 min
at 4 °C) with various drugs, peptides, or ATP. Incubations were
carried out with tumbling for 1 h at 4 °C. The beads were then
thoroughly washed with cold buffer B containing 0.6 M KCl, boiled for 5 min in reducing Laemli loading buffer, and analyzed by
SDS-PAGE and Western blotting with appropriate antibodies or by
autoradiography of dried gels.
ATP-Sepharose Binding Assay--
Co-immunoprecipitation of Hsc70 and p23 with Hsp90--
For
investigation of the influence of novobiocin on Hsp90 association with
the co-chaperones Hsc70 and p23, 1 mM novobiocin was added
to reticulocyte lysate. After 30 min on ice, samples (25 µl) were
diluted in 400 µl of buffer containing 10 mM Tris-HCl, 1 mM MgCl2, 0.2% Tween 20, 10 mM
Na2MoO4, pH 7.5, and incubated for 2 h at
4 °C with 2 µg of an Hsp90 antibody (SPA-771, Stressgen) specific
for the Hsp90 amino terminus. Protein A-Sepharose (Amersham Pharmacia
Biotech) was added to all samples, which were then rotated for an
additional 2 h. Sepharose beads were washed 3-4 times with dilution buffer and processed for SDS-PAGE as described above. Hsp90
immunoprecipitates were analyzed by Western blotting with antibodies
specific for either Hsc70 or p23.
Antibodies--
Hsp90 antibodies recognizing epitopes in either
the amino terminus (amino acids 2-12; SPA-771) or carboxyl terminus
(amino acids 604-697; SPA-830), as well as the Hsc70 antibody SPA-822 were purchased from StressGen Biotechnologies Corp. (Victoria, British
Columbia, Canada). Monoclonal antibody to p23 and Hsp90 antibody H9010
were gifts from Dr. David Toft (Mayo Clinic, Rochester, MN).
Peptide Synthesis--
Selected peptides were synthesized by
Research Genetics (Huntsville, AL) using solid phase peptide synthesis.
Both wild type and mismatched sequences were checked by Edman chemistry
in a peptide sequencer, and peptide purity was determined by mass
spectroscopy. All peptides were soluble in water.
Western Blotting--
Immunoprecipitates or 10-20 µl of
translation lysate were separated on 10% SDS-polyacrylamide gels,
transferred to nitrocellulose membranes by electroblotting, and blocked
for 2 h with a solution containing 5% nonfat dry milk, 10 mM Tris-HCl, pH 7.5, 2.5 mM EDTA, pH 8, 50 mM NaCl, and 0.05% Tween 20. The membranes were probed
with indicated primary antibodies, followed by secondary antibodies
conjugated to horseradish peroxidase, and signals were detected using
chemiluminescence reagents (Pierce).
Effect of Point Mutations within the Amino-terminal Hsp90
Nucleotide/GA/Radicicol-binding Domain on Hsp90 Binding to
Novobiocin-Sepharose--
Several amino-terminal point mutations known
to abrogate GA and radicicol binding to Hsp90 were tested for their
ability to affect binding to immobilized novobiocin. Previous analysis
demonstrated that the mutants D92A, G94D, G113D, G131/4/6V, and G182D
each displayed markedly impaired GA and radicicol binding (16, 20). In
contrast, with the exception of G113D, these mutants bound to
novobiocin-Sepharose as well as or better than did wild type Hsp90
(Fig. 1A). Additionally, the
amino-terminal Hsp90 fragment containing the GA/radicicol-binding site
(amino acids 1-222) failed to bind to immobilized novobiocin (Fig.
1B, and (25)). Although the strongest binding to immobilized
novobiocin was observed with the full-length point mutants K111A and
G182D, the same mutations when made in the amino-terminal fragment of
Hsp90 did not result in binding of this region to novobiocin (Fig.
1B).
Analysis of Carboxyl-terminal Hsp90 Truncation Fragments for
Binding to Novobiocin-Sepharose--
Because the amino terminus of
Hsp90 did not bind novobiocin, we analyzed several
carboxyl-terminal truncation fragments
for binding to novobiocin-Sepharose (Fig. 2 and Fig.
3). Although the longest
carboxyl-terminal fragment, containing amino acids 221-728 ( Binding of Hsp90 Carboxyl-terminal Truncation Fragments to
ATP-Sepharose--
Since novobiocin competitively inhibits ATP binding
to gyrase B, and because ATP inhibited Hsp90 binding to
novobiocin-Sepharose, we tested whether the several carboxyl-terminal
Hsp90 truncations that demonstrated novobiocin binding also bound to
immobilized ATP in a manner competable by novobiocin. Inhibition of Carboxyl-terminal Hsp90 Truncation Fragment Binding
to Novobiocin-Sepharose by a Soluble Peptide--
Because deletion of
amino acids 657-677 markedly reduced the binding of Purified GST-Hsp90 Proteins Bind to Novobiocin- and
ATP-Sepharose--
In order to exclude spurious results due to
possible dimerization between the various in vitro
translated chicken Hsp90 constructs used in this study and the
endogenous Hsp90 present in rabbit reticulocyte lysate (since such
heterodimerization could produce binding artifacts mediated by rabbit
Hsp90), we repeated several experiments using purified GST-Hsp90
proteins. First, we demonstrated that GST-C3 (a carboxyl-terminal Hsp90
fusion protein) bound to ATP-Sepharose and that binding was competed by
excess ATP (Fig. 6A). As
expected, GST-C1 (an amino-terminal Hsp90 fusion protein) also bound to
ATP-Sepharose. However, GST-C3 binding to ATP-Sepharose was
specifically competed by the peptide derived from amino acids 663-676
of Hsp90, whereas GST-C1 binding was not (Fig. 6B). Next, we
demonstrated that GST-Wt Hsp90 and GST-C3, but not GST-C1, bound to
novobiocin-Sepharose in a manner competable by excess novobiocin (Fig.
6C). GST-C3 binding to immobilized novobiocin was also
specifically competed by the soluble peptide derived from the Hsp90
carboxyl terminus (Fig. 6D). Finally, we examined the
efficiency of competition of soluble ADP, ATP, CTP, and GTP with
ATP-Sepharose binding of GST-C3 (Fig. 6E). The order of
efficiency was found to be ATP > ADP > GTP > CTP.
These results are in contrast to the nucleotide affinity of the
amino-terminal domain, which shows a distinct preference for ADP over
ATP (16).
Novobiocin Interferes with Hsp90-Hsc70 and Hsp90-p23
Association--
Hsp90 participates in at least two multichaperone
complexes. One complex contains Hsc70, whose binding site overlaps the
carboxyl-terminal dimerization domain identified in this study to
contain the novobiocin-binding site (28, 29). An alternative Hsp90
multichaperone complex contains an acidic protein, termed p23, that
binds to Hsp90 in an ATP-dependent fashion (30). The
binding site of p23 is not fully characterized, but it is not confined
to the isolated amino terminus (amino acids 1-221), although mutations
in this region certainly affect p23 binding to full-length Hsp90 (16).
Residues in both amino-terminal and carboxyl-terminal portions of Hsp90 were found necessary for binding of SBA1, a yeast homolog of p23 (31).
Because novobiocin binds to a unique site on Hsp90, we wished to
determine whether the drug might disrupt both Hsc70- and p23-containing
multichaperone complexes. To perform this experiment, we made use of
the fact that rabbit reticulocyte lysate contains copious amounts of
both Hsp90-containing multichaperone complexes. We added novobiocin (1 mM) to reticulocyte lysate for 30 min on ice, and then we
immunoprecipitated Hsp90 using an amino-terminally directed antibody
(SPA-771). Following SDS-PAGE and electrotransfer, resultant blots were
probed for p23 and Hsc70. Whereas p23 and Hsc70 were both readily
co-immunoprecipitated with Hsp90 from untreated reticulocyte lysate,
novobiocin preincubation caused a marked decrease in the amounts of
both p23 and Hsc70 co-precipitated with Hsp90 (Fig.
7).
Novobiocin, a coumarin-type antibiotic, antagonizes Hsp90 function
in vitro and in vivo in a manner similar to GA
and radicicol, two structurally different small molecules that both
bind to an amino-terminal nucleotide-binding pocket on the chaperone
(15, 16, 19, 20, 25). However, this study demonstrates that the
structural requirements for novobiocin binding to Hsp90 are unique.
First, several point mutations in the amino terminus of the chaperone
that abrogate both GA and radicicol binding either did not affect or
actually augmented novobiocin binding. Second, an amino-terminal
fragment comprising the GA/radicicol-binding domain failed to bind to
immobilized novobiocin. In contrast, analysis of progressively smaller
carboxyl-terminal Hsp90 peptides revealed the novobiocin-binding site
to be contained within amino acids 538-728. Within this region, the
removal of amino acids 657-677 severely compromised novobiocin
binding, and a synthetic peptide composed of amino acids 663-676
efficiently competed the binding of Hsp90 to immobilized novobiocin.
Thus, these data localize the novobiocin-binding site to a region in
Hsp90 known to be important both for its dimerization and for
association of other co-chaperones.
It has been proposed by several investigators that Hsp90 contains two
distinct chaperone sites (14, 22, 32), one in the amino terminus and
one in the carboxyl terminus of the protein, and that these sites are
linked by a charged domain whose function may be to modulate the
interaction of both chaperone domains (23). Although possible effects
of the charged domain on the chaperone activity/conformation of the
carboxyl terminus are not known, our data suggest that the presence of
the charged domain in the absence of the amino terminus clearly
inhibits novobiocin binding to the carboxyl terminus. It is not certain
if both chaperone domains operate independently of each other, but ATP
(or GA) occupancy of the amino-terminal nucleotide-binding site
certainly affects the binding of co-chaperones to the carboxyl
terminus, whereas the binding of specific co-chaperone proteins to the
carboxyl terminus negatively impacts the ability of the amino terminus to bind nucleotide or GA (16, 33). Our current data support the
existence of cross-talk between the amino and carboxyl ends of Hsp90,
since point mutations that disrupt ATP/GA binding to the amino terminus
markedly enhanced novobiocin binding to the carboxyl terminus.
Additionally, novobiocin binding to the carboxyl terminus of Hsp90
antagonizes the binding of GA and radicicol to the amino terminus (25).
By further supporting functional interaction between amino- and
carboxyl-terminal domains of Hsp90, Hartson et al. (21) have
shown that molybdate ion interacts with the carboxyl terminus of the
chaperone in a region that, in light of our results, overlaps the
novobiocin-binding site and that such interaction influences the
conformation of the amino terminus. Prior association of GA with Hsp90
prevented the chaperone from attaining the molybdate-favored
conformation (21). Taken together these data support a model in which
the conformational state of either end of Hsp90 may affect the
conformation/function of the opposite end, with the middle charged
domain perhaps mediating such interactions.
Surprisingly, binding of carboxyl-terminal Hsp90 fragments to
novobiocin-Sepharose was competed not only by excess novobiocin but
also by ATP. Additionally, the smallest carboxyl-terminal Hsp90
fragment, Binding of Although we found no evidence that our results with in vitro
translated Hsp90 carboxyl-terminal fragments were due to interference by rabbit Hsp90 present in the reticulocyte lysate (data not shown), we
confirmed our findings using purified GST-Hsp90 fusion proteins. Thus a
carboxyl-terminal GST-Hsp90 fusion protein (GST-C3) behaved exactly as
the in vitro translated Although controversial, a precedent exists for a second ATP-binding
site in the carboxyl terminus of Hsp90, analogous to the two
nucleotide-binding sites found in the Hsp110 chaperone family (34).
Indeed, an early study by Csermely and Kahn (35) identified the
presence of an ATP-binding consensus sequence in the carboxyl-terminal half of Hsp90. Although the recent identification and extensive characterization of the amino-terminal nucleotide-binding site, together with the reported lack of ATP dependence of the chaperone activity mediated by the Hsp90 carboxyl terminus, have focused attention away from possible nucleotide interactions with other portions of this chaperone, careful kinetic analysis of
ATP-dependent Hsp90 activities suggests the cooperativity
of two nucleotide-binding sites (36). Whether these sites represent two
amino-terminal binding domains of an Hsp90 dimer, or perhaps one
carboxyl- and one amino-terminal domain, remains to be determined.
The physiologic significance of novobiocin binding to the Hsp90
carboxyl terminus is amply demonstrated by the ability of this
antibiotic to destabilize and deplete a series of Hsp90 client proteins, similar to the effects of both GA and radicicol (25). Further
evidence of the biologic importance of novobiocin binding to Hsp90 is
supplied by the data in this study showing that the drug interferes
with both Hsc70 and p23 association. Since Hsc70 and p23 are components
of two distinct multichaperone complexes formed around Hsp90, these
results suggest that novobiocin binding disrupts both
Hsp90-Hsc70-p60Hop and Hsp90-p50 (or immunophilin)-p23
complexes. This is in contrast to the effects of GA and radicicol that
disrupt only p23-containing Hsp90 complexes (1, 20, 37). Thus,
novobiocin, besides mimicking the biologic effects of GA and radicicol,
may have an additional negative impact on Hsp90 function not seen with
the other drugs, although this hypothesis remains to be examined.
We thank David Toft for chicken Hsp90
plasmids and antibodies to p23 and Hsp90. We also thank David Toft and
Timothy Haystead for helpful discussions.
*
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.
Published, JBC Papers in Press, August 16, 2000, DOI 10.1074/jbc.M003701200
The abbreviations used are:
GA, geldanamycin;
PAGE, polyacrylamide gel electrophoresis;
GST, glutathione
S-transferase;
Wt, wild type.
The Heat Shock Protein 90 Antagonist Novobiocin Interacts with a
Previously Unrecognized ATP-binding Domain in the Carboxyl Terminus of
the Chaperone*
,
Department of Cell and Cancer Biology,
Medicine Branch, NCI, National Institutes of Health,
Rockville, Maryland 20850, the § Department of
Biochemistry and Molecular Biology, Mayo Clinic,
Rochester, Minnesota 55905, and the ¶ CNRS-UPR Cochin-Port
Royal, 24 rue de Foubourg St. Jacques, 75014 Paris, France
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
cDNA
(amino acids 1-728), full-length Hsp90 containing various
amino-terminal point mutations, and the 
221-728 (1), 303-728
(2), 380-728 (3), 3 lacking amino acids 657-677
(3), and 538-728 (4) carboxyl-terminal chicken Hsp90
truncation fragments, subcloned in pGEM-7Z (Promega Corp., Madison,
WI), were gifts of Dr. David Toft (Mayo Clinic, Rochester, MN), and
their preparation was described previously (26). Wild type and mutated
(K111A, G182D) amino-terminal (amino acids 1-222) fragments of chicken
Hsp90 were obtained from wild type or the corresponding previously
mutated full-length chicken Hsp90 cDNA by polymerase chain reaction
using primers designed to contain BamHI (for 5') and
EcoRI (for 3') restriction sites, and the DNA fragments were
then subcloned in pBluescript II SK (Stratagene, La Jolla, CA).
Truncation mutants 380-539 (3-4), 3, and 4 lacking
amino acids 657-677 (3 and 4, respectively) were obtained
by polymerase chain reaction and cloned in pBluescript II SK as above.
The purified fusion proteins GST-Wt Hsp90 (amino acids 1-728), GST-C1
(Hsp90 amino acids 1-332), and GST-C3 (Hsp90 amino acids 446-728)
were kind gifts of David Toft and Maria-Grazia Catelli (Mayo Clinic and
CNRS, Paris, France, respectively).
-Phosphate-linked
ATP-Sepharose (Upstate Biotechnology, Inc., Lake Placid, NY) was
equilibrated in molybdate buffer (10 mM Tris-HCl, 5 mM MgCl2, 10 mM
Na2MoO4, 0.2% Tween 20, pH 7.5). Aliquots of
in vitro translates (10-20 µl) or 4 µg of purified
GST-Hsp90 proteins were diluted in 300 µl of molybdate buffer and
mixed, while tumbling, with ATP-Sepharose (100 µl) for 2 h at
4 °C. Samples were washed 3-4 times with cold molybdate buffer, and
bound proteins were eluted and analyzed as described above. To study
nucleotide competition of binding to ATP-Sepharose, we incubated 4 µg
of purified GST-C3 with increasing concentrations of the sodium salts of ADP, ATP, CTP, and GTP (all from Sigma) for 1 h at 4 °C on a
rotary shaker prior to assessment of ATP-Sepharose binding.
RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
Binding of Hsp90 point mutants and
amino-terminal truncations to novobiocin-Sepharose. Full-length
(A) or amino-terminal (B)
[35S]methionine-labeled chicken Hsp90 wild type
(Wt) and point mutated proteins were translated in rabbit
reticulocyte lysate as described under "Materials and Methods," and
aliquots of protein (equal radioactivity) were incubated with
novobiocin resin in buffer B for 1 h at 4 °C and then
thoroughly washed with buffer B containing 0.6 M KCl.
Proteins bound on beads were analyzed by SDS-PAGE and autoradiography.
Binding of the same lysates to GA-Sepharose beads is shown for
comparison.
1),
failed to bind novobiocin, removal of the charged domain between
residues 221 and 303 (2) restored binding (Fig. 3A).
Analysis of successive truncations revealed that binding to novobiocin
resided in a carboxyl-terminal Hsp90 fragment containing amino acids
538-728 (4) (see Figs. 2 and 3C). Deletion of amino acids 657-677 from both 3 (3) and 4 (4)
significantly reduced binding to novobiocin-Sepharose (Fig.
3C). Surprisingly, binding of both the full-length point
mutant G182D and the carboxyl-terminal Hsp90 truncations 2, 3,
and 4 to immobilized novobiocin was effectively competed by both
excess soluble novobiocin and ATP (Fig. 3 and Fig.
4, A and B).
Finally, increasing concentrations of soluble novobiocin were able to
inhibit competitively the binding of 3 to novobiocin-Sepharose (Fig.
3D).
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Fig. 2.
Map of the chicken Hsp90 constructs employed
in the novobiocin and ATP binding studies, and their relative binding
efficiency to novobiocin-Sepharose. Wild type (Wt)
chicken Hsp90 consists of 728 amino acids. Various mutated amino acids
are marked by an X; removal of amino acids 657-677 is
symbolized by dots.
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Fig. 3.
Binding of Hsp90 carboxyl-terminal fragments
and the full-length point mutant G182D to novobiocin-Sepharose:
competition by soluble novobiocin and ATP. A,
[35S]methionine-labeled chicken Hsp90 carboxyl-terminal
fragments translated in reticulocyte lysate were incubated with or
without novobiocin (1 mM) or sodium ATP (10 mM)
for 1 h at 4 °C, and then equal amounts of novobiocin beads
were mixed with the proteins and further incubated for 1-2 h. The
beads were washed as in Fig. 1, and the bound proteins were analyzed by
SDS-PAGE and autoradiography. B,
[35S]methionine-labeled point mutant G182D was translated
in vitro and processed as in A. C,
binding of the [35S]methionine-labeled carboxyl-terminal
fragments 3 and 4 to novobiocin-Sepharose is markedly reduced if
amino acids 657-677 are deleted, yielding the respective shorter
variants 3 and 4. D,
[35S]methionine-labeled 3 was incubated as described
under "Materials and Methods" with increasing concentrations of
soluble novobiocin prior to addition of novobiocin-Sepharose. The
percent of 3 that bound to novobiocin-Sepharose was plotted against
the concentration of soluble novobiocin competitor. The proteins were
synthesized, incubated with the novobiocin resin, processed, and
analyzed as above.
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Fig. 4.
Binding of Hsp90 carboxyl-terminal fragments
to ATP-Sepharose: Competition with soluble novobiocin and ATP.
A, [35S]methionine-labeled chicken Hsp90
carboxyl-terminal fragments translated in reticulocyte lysate were
incubated with or without novobiocin (5 mM) or sodium-ATP
(10-15 mM) for 1 h at 4 °C. Equal amounts of ATP
beads were added, and the tubes were further incubated, washed, and
analyzed by autoradiography as described under "Materials and
Methods." B, 4 was labeled and translated in
vitro as described above, and equal aliquots of protein were
incubated for 1 h with increasing (5-500 µM)
concentrations of sodium ATP. ATP beads were added and further
incubated for 1-2 h and then washed and processed as described under
"Materials and Methods." Dried gels were analyzed by
autoradiography. C, autoradiographs of the gels in
B were scanned into a Macintosh 9500 computer, and band
densities were determined using Adobe Photoshop 5.0 and NIH Image
software. The fraction of bound 4 was plotted as a function of ATP
concentration after setting the value obtained from samples incubated
without ATP to 1.0.
1 did not bind
to ATP-Sepharose, as predicted from its failure to bind to novobiocin,
but 2, 3, and 4 did bind to immobilized ATP (Fig.
4A). Also predicted from its failure to bind to novobiocin,
3 did not bind to ATP-Sepharose. Finally, soluble ATP and
novobiocin both competitively inhibited Hsp90 carboxyl-terminal
fragment binding to ATP-Sepharose (Fig. 4, B and
C, and data not shown).
3 and 4 to
immobilized novobiocin, we synthesized a peptide encompassing this
sequence in order to determine if this region alone were sufficient to
bind to novobiocin-Sepharose. A peptide of sequence YETALLSSGFSLED,
corresponding to amino acids 663-676 of Hsp90, was able to inhibit
novobiocin binding to 3, 4, and the full-length G182D point
mutant (Fig. 5). In contrast, a
mismatched peptide, of sequence YTEFLSASLEGLSD, had minimal effect even
at the highest concentrations used (Fig. 5).
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Fig. 5.
Hsp90 binding to novobiocin-Sepharose:
competition by a soluble peptide containing amino acids 663-676 of
Hsp90. A, schematic representation of the localization
of the sequence in Hsp90 on which the synthetic peptide is based.
B, the left panel shows the inhibitory effect of
increasing concentrations of "sense" peptide (PP) on
binding of the carboxyl-terminal fragment 3 to novobiocin beads.
[35S]Methionine-labeled 3 was incubated without or
with the respective concentrations of peptide (0.1 or 1 mM)
and novobiocin beads in buffer B, processed, and analyzed by
autoradiography. The central panel represents a similar
experiment performed with the deletion fragment 4, in the presence
of either sense peptide (PP) or the mismatch peptide
(MP). The right panel shows the inhibitory effect
of PP on the binding of full-length mutant G182D to
novobiocin-Sepharose under similar conditions to those described
above.
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Fig. 6.
Purified GST-Hsp90 fusion proteins bind
to novobiocin- and ATP-Sepharose. A, the Hsp90
carboxyl-terminal fusion protein GST-C3 or amino-terminal fusion
protein GST-C1 (4 µg each) were incubated with ATP-Sepharose beads in
the presence or absence of excess ATP. Beads were processed as
described under "Materials and Methods" and analyzed by SDS-PAGE
followed by silver staining. B, GST-C3 and GST-C1 (4 µg
each) were preincubated with either 10 mM sense peptide
(PP) or "mismatch" peptide (MP) prior to
analysis of ATP-Sepharose binding as in A. C, GST-Wt Hsp90,
GST-C3, or GST-C1 (4 µg each) were incubated with increasing
concentrations of soluble novobiocin prior to analysis of binding to
novobiocin-Sepharose. Samples were analyzed by SDS-PAGE followed by
silver staining. D, GST-C3 (4 µg) was incubated with 10 mM sense peptide (PP) or mismatch peptide
(MP) prior to analysis of novobiocin-Sepharose binding.
E, GST-C3 (4 µg) was incubated with increasing
concentrations of various nucleotides prior to analysis of
ATP-Sepharose binding.
View larger version (19K):
[in a new window]
Fig. 7.
Novobiocin inhibits association of p23 and
Hsc70 with Hsp90. Rabbit reticulocyte lysate was incubated without
(lane 1) or with (lane 2) 1 mM
novobiocin for 1 h at 4 °C and then immunoprecipitated with
Hsp90-directed antibody SPA-771. After SDS-PAGE and transfer to
nitrocellulose, the blots were probed for Hsp90, Hsc70, or p23.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
4, that bound to immobilized novobiocin also bound to
ATP-Sepharose, and this binding was competed by both novobiocin and
ATP. Similar to its effects on novobiocin binding, deletion of amino
acids 657-677 from either 3 or 4 carboxyl-terminal Hsp90
fragments reduced binding to ATP-Sepharose by greater than 90%,
whereas the synthetic peptide duplicating the amino acid sequence from
residues 663 to 676 effectively blocked Hsp90 binding to immobilized ATP.
4 to ATP-Sepharose was competitively inhibited by both
soluble ATP and novobiocin, suggesting that the novobiocin-binding domain which we have mapped to the carboxyl terminus of Hsp90 may
overlap a second nucleotide-binding site on the chaperone. An Hsp90
fragment lacking the amino-terminal 222 amino acids but containing the
charged domain failed to bind ATP-Sepharose just as it failed to bind
to novobiocin-Sepharose, suggesting that the charged domain may
regulate nucleotide access to the carboxyl-terminal site. In support of
this hypothesis, removal of the charged domain restored ATP binding to
carboxyl-terminal Hsp90 peptides.
4 carboxyl-terminal fragment, not
only with respect to binding to novobiocin- and ATP-Sepharose, but also
with respect to the ability of the soluble peptide to compete such
binding. Analysis of the efficiency of various nucleotides as
competitors of GST-C3 binding to ATP-Sepharose revealed that ATP was
more efficient than ADP in this regard. In contrast, previous data
demonstrated that the amino-terminal nucleotide-binding site has a
10-fold greater affinity for ADP as compared with ATP (16). The fact
that GTP was only minimally able and CTP completely unable to reduce
the binding of GST-C3 to ATP-Sepharose lends further support to the
specificity of our data.
ACKNOWLEDGEMENTS
FOOTNOTES
Please send all correspondence. Tel.: 301-402-3128 (Ext. 318);
Fax: 301-402-4422; E-mail: len@helix.nih.gov.
ABBREVIATIONS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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