(Received for publication, November 20, 1996, and in revised form, December 17, 1996)
From the Department of Cell Biology, Duke University Medical Center, Durham, North Carolina 27710
GRP94, the endoplasmic reticulum paralog of hsp90, has recently been identified as a peptide and adenine nucleotide-binding protein. To determine if adenine nucleotides directly contribute to the regulation of GRP94 peptide binding activity, an in vitro peptide binding assay was developed. Using purified GRP94, we observed specific, saturable, temperature-sensitive binding of the peptide VSV8, a known in vivo ligand. ATP was without effect on VSV8 binding to GRP94, whether present during or subsequent to peptide binding. To evaluate the interaction of GRP94 with adenine nucleotides, the ATP binding and hydrolysis activities were directly assayed. Only negligible binding of ATP to GRP94 was observed. In addition, analysis of the GRP94 adenine nucleotide content indicated that GRP94 did not copurify with bound adenine nucleotides. GRP94 preparations exhibited low ATPase and apparent autophosphorylation activities. Further purification, combined with inhibitor studies, indicated that both activities were the result of trace contamination (<0.1%) with casein kinase II. On the basis of these data, we propose that the peptide binding activity of GRP94 is adenine nucleotide-independent and that ATP binding and hydrolysis are not inherent properties of GRP94.
Molecular chaperones are abundant, ubiquitous proteins that participate in a variety of cellular processes, such as protein folding and assembly, protein translocation across membranes, and protection from cell stress (1-3). The highly conserved hsp60,1 hsp70, and hsp90 families of stress proteins are among the most prominent chaperones and are noteworthy for their multi-compartmental localization within the cell and broad phylogenetic distribution (1, 3). Substantial insights into the molecular mechanism of chaperone function have been obtained in studies of the hsp60 and hsp70 proteins (3-7). For these proteins, chaperone activity is expressed through cycles of (poly)peptide binding and release, the kinetics of which are regulated through the binding and hydrolysis of ATP (1, 7, 8).
The molecular basis of hsp90 function is poorly understood. GRP94, the endoplasmic reticulum (ER) hsp90 paralog, is induced by the accumulation of unfolded proteins in the ER, can be found in association with nascent polypeptides in the ER lumen, and is thus likely to display chaperone activity (9-11). The identification of GRP94 as a tumor rejection antigen of murine chemical sarcomas has led to the discovery that GRP94 is a peptide-binding protein (12-15). Furthermore, GRP94 has been demonstrated to bind and hydrolyze ATP (12, 16) and undergo autophosphorylation (17). On the basis of these observations, it would appear that GRP94, and by inference, the hsp90 family of molecular chaperones, function in a manner analogous to the hsp60 and hsp70 families of molecular chaperones.
Using a peptide substrate previously identified as an in vivo ligand (15), we report that GRP94 displays saturable, specific, temperature-sensitive peptide binding activity that is insensitive to the presence of adenine nucleotides. Because we presumed that the GRP94 ATPase activity is related to its chaperone function, the ability of GRP94 to bind and hydrolyze ATP were analyzed in parallel with BiP (GRP78), an ER-resident ATPase- and ATP-binding protein (18, 19). Equilibrium ATP binding studies indicate that GRP94 is not an ATP-binding protein. Low levels of ATPase and apparent autophosphorylation activity were reproducibly observed with the purified protein. Pharmacological studies and further purification indicated that both activities reflected fractional (<0.1%) contamination with casein kinase II. We conclude that the peptide binding activity and presumably the chaperone function of GRP94 are ATP-independent.
All chemicals were of analytical grade. Bovine
IgG, Dowex 1 X 8-50 (Cl), activated charcoal,
spermidine, and polylysine were obtained from Sigma.
ATP and GTP were purchased from Boehringer Mannheim. [
-32P]ATP (3000 Ci/mmol), [
-32P]ATP
(6000 Ci/mmol), and Na125I were obtained from Amersham
Corp.
GRP94 was purified from rough microsomes prepared by the method of Walter and Blobel (20) as described previously (21). The BiP-enriched fractions from the MonoQ stage of the GRP94 purification (21) were pooled and purified by hydroxyapatite chromatography. The BiP pool, dialyzed in 10 mM potassium phosphate, pH 6.8, 20 mM NaCl, 0.5 mM Mg(OAc)2 (buffer A) was loaded onto a 5-ml hydroxyapatite column and BiP eluted with a 40-ml gradient of 10 to 450 mM potassium phosphate, pH 6.8, in buffer A. BiP-enriched fractions were identified by SDS-PAGE, pooled, and concentrated by centrifugal ultrafiltration (Centricon-30; Amicon, Beverly, MA).
Peptide Binding AssayPeptide VSV8 (RGYVYQGL), has been
identified as an in vivo ligand of GRP94 (15). A peptide
corresponding to the VSV8 sequence with an additional N-terminal
cysteine, termed C-VSV8, was synthesized by standard Fmoc
(N-(9-fluorenyl)methoxycarbonyl) chemistry by Applied
Analytical Industries (Chapel Hill, NC). Iodination of C-VSV8 was
performed by the Iodobeads procedure (Pierce) and unincorporated [125I]iodine removed by anion exchange chromatography on
Dowex 1 X 8-50 (Cl) resin. The specific activity of
the [125I]C-VSV8 was typically 0.1-0.25 µCi/µg.
Peptide binding assays were performed as follows. GRP94 (14 µg) was
incubated with 37.5 µM [125I]C-VSV8 in 100 µl of buffer B (110 mM KOAc, 20 mM NaCl, 25 mM KOH-Hepes, pH 7.2, 2 mM MgCl2,
and 0.1 mM CaCl2) for 1 h at 37 °C or
10 min at 50 °C. Samples were applied to 1.5-ml S-200 columns equilibrated in buffer B. Fractions were collected and analyzed by
SDS-PAGE to identify the GRP94 peak, and in parallel the
125I content was determined by counting. Background
values, derived from chromatography of the peptide in the absence of
GRP94, were subtracted from all points. To analyze the effect of ATP on
peptide binding, GRP94 was incubated with [125I]C-VSV8 in
the presence or the absence of 1 mM ATP for 1 h at 37 °C. In addition, GRP94 was incubated with peptide for 1 h
and subsequently with 1 mM ATP for an additional 30 min.
Equilibrium [125I]C-VSV8 binding studies were performed
as described in the figure legends, with the following modification:
GRP94-peptide complexes were resolved by chromatography on a 20-ml
S-200 column equilibrated in buffer B.
GRP94 and BiP (each at 0.35 µM) were incubated with 0-50 µM
[-32P]ATP (specific activity, 100-150 µCi/nmol) for
1 h at 30 °C in 100 µl of buffer B. Bound versus
free nucleotides were separated by vacuum filtration on BA85
nitrocellulose filters (Schleicher & Schuell) using a vacuum filtration
manifold (Pharmacia Biotech Inc.). Filters were washed with 3 × 2 ml of ice-cold buffer B and dried, and 32P was determined
by liquid scintillation counting. All assays were performed in
triplicate, and background values, determined in the presence of a
50-fold molar excess of unlabeled ATP, were subtracted from all
points.
Purified GRP94 and BiP (500 µg) were incubated with 0.25 M perchloric acid for 5 min on ice. Denatured proteins were removed by centrifugation at 8,000 rpm for 10 min, and the supernatant was collected, neutralized by the addition of 1 N KOH, and centrifuged for 10 min at 8,000 rpm. The nucleotide content of the supernatant fractions was determined by MonoQ chromatography using a gradient of 50 mM NaCl, 5 mM sodium phosphate, pH 6.8 to 500 mM NaCl, 5 mM sodium phosphate, pH 6.8. Nucleotide peaks were monitored by the A254 and quantitated against known standards.
ATP Hydrolysis and Phosphorylation AssaysGRP94, BiP, and
BSA (each at 0.5 µM) were incubated with 0-100
µM [-32P]ATP (specific activity 150-300
µCi/nmol) in buffer B for 1 h at 37 °C in a final volume of
25 µl. Reactions were performed in triplicate. At the end of the
incubation, samples were diluted into 975 µl of a suspension of 5%
activated charcoal, 10 mM phosphoric acid, pH 2.3, and
incubated on ice for 30 min. Charcoal with bound nucleotides was
pelleted by centrifugation for 2 min at 2,500 rpm, and 0.5 ml of the
supernatant, containing 32P-labeled inorganic phosphate,
was assayed by liquid scintillation spectrometry. ATP hydrolysis
observed in the presence of BSA was subtracted as background.
To assay for GRP94 phosphorylation, GRP94 (0.5 µM) was
incubated with 10 µM [-32P]ATP in 25 µl of buffer B for 60 min at 37 °C. Following the incubation,
GRP94 was precipitated with 10% trichloroacetic acid and analyzed on
10% SDS-PAGE gels. Phosphorylated species were detected and
quantitated using a Fuji MacBas1000 phosphorimaging system (Fuji
Medical Systems, Stamford, CT).
Purified GRP94 (75 µg) was incubated with 40 µl of a 50% slurry of ConA-Sepharose (Pharmacia) at 4 °C for 4 h in 0.5 ml of buffer B. After centrifugation for 2 min at 2,500 rpm, the unbound GRP94 was removed, and the resin was washed with 1 ml of buffer B. The sample was divided into two aliquots and washed 4 × 15 min with 1 ml of either buffer B alone or buffer B supplemented with 1 M NaCl. Both aliquots were washed back into buffer B and assayed for GRP94 phosphorylation activity as described above.
Peptide binding to GRP94
was assayed with VSV8, the immunodominant peptide of VSV. VSV8 has been
identified as a native GRP94 ligand in VSV-infected cells (15) and thus
represents an appropriate peptide for in vitro binding
studies. The peptide used in this study was synthesized with an
N-terminal cysteine and is denoted C-VSV8. To determine if GRP94 was
capable of binding C-VSV8 in vitro, purified GRP94 was
incubated with [125I]C-VSV8 for either 1 h at
37 °C or 10 min at 50 °C, and bound versus free
peptide was separated by gel filtration chromatography (Fig.
1A). A peak of 125I-labeled
peptide (fractions 7-8) was observed that co-eluted with GRP94 and was
resolved from free peptide (Fig. 1A). Peptide binding was
markedly stimulated at higher (50 °C) temperatures, suggesting that
there exists a kinetic barrier to binding, which is as yet
unidentified. Binding of C-VSV8 to GRP94 was saturable with an apparent
Kd of 15 µM (Fig. 1B). In
addition to exhibiting saturation kinetics, binding was specific, with
<15% binding being observed in the presence of a 40-fold excess of unlabeled peptide (data not shown). As an additional control, peptide
binding reactions were performed with IgG, and no specific binding was
observed (Fig. 1C).
For hsp70 proteins a conformational change associated with ATP binding stimulates release of bound peptides (7, 22). Accordingly, peptide binding to BiP is greatly diminished in the presence of ATP (23). In light of reports that GRP94 can bind ATP (16) is an ATPase (12) and possesses autophosphorylation activity (17), the role of ATP in the regulation of peptide binding by GRP94 was evaluated. In these experiments, GRP94 was incubated with [125I]C-VSV8 in the presence or the absence of 1 mM ATP, and bound versus free peptide resolved as described previously. Unexpectedly, the amount of peptide bound to GRP94 under both conditions was nearly identical (Fig. 1C). GRP94 was also incubated with C-VSV8 for 1 h prior to the addition of 1 mM ATP. This sequence of ATP addition was without effect on VSV8 binding; rather, increased binding, a consequence of the extended incubation time, was observed (Fig. 1C).
Analysis of ATP Binding to GRP94The observation that adenine
nucleotides were without effect on the peptide binding activity of
GRP94 suggests that ATP binding may not be an intrinsic biochemical
property of GRP94. Because the methods used previously to assess the
nucleotide binding properties of GRP94 were indirect (12, 16), the ATP
binding properties of GRP94 were directly assayed. GRP94 was incubated
with increasing concentrations of [-32P]ATP for 1 h at 30 °C and free versus bound nucleotide separated by
vacuum filtration. As a positive control, studies were performed in
parallel with BiP, an ATP-binding protein (18). As depicted in Fig.
2A, BiP bound ATP in a saturable manner,
whereas the ATP binding activity of GRP94 was near background levels.
Analysis of the data by Scatchard plot indicated that BiP bound ATP
with an apparent Kd of 5.4 µM, with
0.67 mol of ATP bound per 1 mol of BiP (Fig. 2B). GRP94
bound ATP with an apparent Kd of 0.24 µM, with 0.026 mol of ATP bound per 1 mol of GRP94.
Clearly, the molar stoichiometry of ATP binding to GRP94 is
inconsistent with an ATP binding activity.
Although little binding of ATP to GRP94 was observed, a scenario in which nucleotide binding was limited by exchange with endogenous nucleotide was considered. To assay for bound nucleotides, the A280/A260 ratio for purified GRP94 and BiP was determined. The ratio for GRP94 was 1.6 compared with 1.2 for BiP, suggesting that nucleotides are not found in association with native GRP94 (data not shown). In addition, the ribonucleotide content of perchloric acid extracts of GRP94 and BiP were analyzed by MonoQ chromatography and UV spectrometry. In agreement with the A280/A260 data, extracts from BiP, but not GRP94, contained bound adenine nucleotides (data not shown).
Kinetics of GRP94-associated ATP HydrolysisIn an attempt to
reconcile reports of GRP94 ATPase activity (12) with the extremely low
molar stoichiometry of ATP binding (Fig. 2), the
kinetics of ATP hydrolysis by GRP94 were evaluated in parallel with
BiP. In these experiments, GRP94 and BiP were incubated with increasing
concentrations of [-32P]ATP for 1 h at 37 °C,
and the amount of ATP hydrolyzed, assayed as 32Pi release,
was determined (Fig. 3A). Low levels of ATP hydrolysis in
GRP94 preparations were detectable. Analysis of the data by Lineweaver-Burk plots indicated that the Km for ATP
was 3.4 µM for GRP94 and 28.6 µM for BiP
and the Vmax was 0.36 pmol/min for GRP94 and
4.76 pmol/min for BiP (Fig. 3B). These data are in general
agreement with previous reports by Li and Srivastava (12) and
Kassenbrock and Kelly (19) with regard to GRP94 and BiP, respectively.
Interestingly, these data indicate that the turnover rate for GRP94 is
0.029 mol/min/mol, corresponding to one molecule of ATP hydrolyzed per
molecule of GRP94 per 34 min. Such low values are without precedent,
even with respect to the documented, sluggish ATPase activities
characteristic of molecular chaperones (8).
Evidence for the Co-purification of Casein Kinase II with GRP94
To determine the origin of the ATP binding and hydrolysis
activities present in our GRP94 preparations, we examined the
possibility that the assayed activities were due to a low enrichment,
high activity contaminant. GRP94, cytosolic hsp90, and several ER
lumenal proteins have previously been observed to co-purify with and be phosphorylated by casein kinase II (CKII), a messenger-independent, serine/threonine protein kinase (24-28). If CKII co-purified with GRP94, it would be predicted on the basis of the abundance of CKII
phosphorylation sites2 that GRP94 would
serve as a CKII substrate. Incubation of GRP94 with 10 µM
[-32P]ATP for 1 h at 37 °C and analysis of the
SDS-PAGE resolved protein by phosphorimaging indicated that GRP94 was
indeed subject to phosphorylation. As depicted in Fig.
4A (lane 1), GRP94 contains covalently associated 32Pi. Quantitation against internal
32Pi standards indicated that under the described
conditions 1.5-4% of the GRP94 was phosphorylated. Inhibition by
heparin, stimulation by polyamines and basic polypeptides, and the
ability to utilize GTP and ATP are diagnostic of CK II activity (28).
When these compounds were included in the assay, the incorporation of
32Pi in GRP94 was affected in a manner consistent with the
presence of CKII. Heparin at 5 µg/ml completely blocked
phosphorylation (Fig. 4A, lane 4), GTP at a
50-fold molar excess reduced phosphorylation by 92% (Fig.
4A, lane 7), and 1 mM spermidine
stimulated GRP94 phosphorylation 2-fold (Fig. 4A, lane
10). To determine whether the ATPase activity associated with
GRP94 also reflected the activity of contaminating CKII, ATPase assays
were performed in the presence of 500 µM GTP, 50 µg/ml
polylysine, or 1 mM spermidine (Fig. 4B). GTP
reduced levels of ATP hydrolysis by 74%, whereas polylysine and
spermidine stimulated the GRP94-associated ATPase activity by 4- and
1.3-fold, respectively. These data support the conclusion that the low
levels of ATP hydrolysis observed with GRP94 preparations can be
explained by the presence of trace levels of CKII.
To further substantiate this conclusion, it was demonstrated that these
activities could be reduced by further purification of GRP94.
ConA-Sepharose was employed as a purification step to remove associated
CKII, because only GRP94 contains high mannose oligosaccharides. GRP94
was bound to ConA-Sepharose, extensively washed with low salt or high
salt buffers, and assayed for phosphorylation activity. Depicted in
Fig. 4C is the phosphorylation activity of the standard
GRP94 preparation (homogenous by protein staining) and the low salt and
high salt washed ConA-Sepharose bound GRP94. Consistent with the data
shown in Fig. 4A, the purified GRP94 preparation was
phosphorylated in the presence of [-32P]ATP and, as
expected, was sensitive to the CKII effectors heparin and spermidine
(Fig. 4C, lanes 1-3). Low salt washing alone
reduced levels of phosphorylation by 50%, whereas the high salt wash
nearly eliminated GRP94 phosphorylation (Fig. 4C,
lanes 4-9). Even after extensive washing, however, a trace
amount of phosphorylation persisted that was sensitive to effectors of
CKII. The ATPase activity associated with GRP94 before and after the
ConA purification was also analyzed. Low salt washing reduced levels of
ATP hydrolysis by 25% and high salt washing further reduced this
activity by 65% (data not shown).
In this communication, we present data demonstrating specific, saturable, and temperature-sensitive binding of a peptide substrate to GRP94 and provide evidence that the peptide binding and release reactions are independent of ATP binding and hydrolysis. These data suggest that the (poly)peptide binding and release processes of GRP94 are regulated in a manner distinct from that identified for the hsp60 and hsp70 families of chaperones.
The finding that the peptide binding activity of GRP94 was independent
of adenine nucloetides led us to re-evaluate previous reports that
GRP94 is an ATP-binding protein and ATPase (12, 16). The ATP binding
and hydrolyzing properties of GRP94 were analyzed in parallel with BiP,
a well characterized ATPase (18, 19, 23). Although apparent binding of
ATP to GRP94 was observed, the low molar stoichiometry of binding
(0.026 mol of ATP bound/mol GRP94), raised the specter of a low
enrichment, ATP-binding contaminant. The observation that GRP94 was
phosphorylated upon incubation with [-32P]ATP,
combined with previous reports demonstrating a propensity of CKII to
copurify with hsp90 and GRP94, further implicated a contaminant protein
as the underlying basis for these activities. Based on the sensitivity
of the CKII ATPase and phosphorylation activities to compounds that are
diagnostic of CKII activity, it was concluded that trace amounts of
this enzyme co-purify with GRP94. It should be noted that the specific
activity of ATP hydrolysis by CKII is quite high, with values up to
5000 pmol ATP hydrolyzed/min/µg of protein reported (29). At this
specific activity, a 0.06% level of CKII contamination (GRP94 purity
of 99.94%) would be sufficient to achieve the observed levels of
ATPase activity and phosphorylation.
It has been established that the lifetimes of hsp60- and hsp70-substrate interactions are governed by the kinetic parameters of ATP binding and hydrolysis (7, 22, 30, 31). In the case of DnaK, the rates of ATP hydrolysis and ADP-ATP exchange are further regulated through interaction with DnaJ and GrpE, respectively (7, 32). Such regulation is reminiscent of GTP-binding proteins, whose interactions with effectors are regulated by the kinetics of GTP binding and hydrolysis (33, 34). In view of the data reported herein, indicating adenine nucleotide-independent peptide binding by GRP94, it is of value to ask whether the peptide binding activity of GRP94 is under regulatory control. It has been noted that the kinetics of ATP binding and hydrolysis of the hsp60 and hsp70 chaperones are quite well matched to the rates of cellular protein synthesis (8). By similar logic, it can be inferred that GRP94-substrate interactions would also be regulated, so that the lifetimes of GRP94-substrate interactions would be of a time frame relevant to protein synthesis and/or protein secretion. To achieve such regulation, we postulate that other as yet unidentified ER components physically interact with GRP94 to enhance the kinetics of substrate binding and/or release. Such factors, we hypothesize, might recognize specific conformations of GRP94, the bound substrate, or both. Should such regulatory factors be compartmentalized within the ER, the interaction of GRP94 with its substrates could be regulated at unique sites, such as the transitional elements-export sites (35, 36).
Because of the high degree of sequence homology (37), it is expected that members of the hsp90 family share a common molecular mechanism of action. Recently, it has been debated whether hsp90 proteins function in an ATP-dependent manner (38). In agreement with this study, it has been recently reported that cytosolic hsp90 does not bind ATP (38), does not contain bound nucleotides (39), and does not possess an ATPase activity (4, 38). Together, these findings provide a strong argument that hsp90 proteins function by an ATP-independent mechanism and will serve to direct future studies on the molecular regulation of hsp90 protein function.